EP1563418A2

EP1563418A2 - Layout-orientated recording of automation information

Info

Publication number: EP1563418A2
Application number: EP03811336A
Authority: EP
Inventors: Heinz Bernhardt; Soeren Moritz
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2002-11-21
Filing date: 2003-10-30
Publication date: 2005-08-17
Also published as: DE10254536A1; WO2004046973A3; US7505821B2; WO2004046973A2; US20070008319A1

Abstract

The invention relates to a system and a method for the graphical recording of system requirements and specifications in electronically readable form. Elements of a plant are graphically represented by selectable components (21). The components (21) are graphically rendered in a relationship (23) to each other and a control-relevant circuitry (24) automatically specified based on the established relationship (23) and prepared in electronic form.

Description

description

Layout-oriented acquisition of automation information

The invention relates to a system and a method for the graphic recording of system requirements and specifications in an electronically evaluable form.

As a starting point for the automation of plants or

Nowadays machines are mainly used for technical drawings. The drawings are designed from the perspective of mechanical or plant engineering or process engineering. In the case of an automation solution to be developed, the requirements and specifications belonging to the system are generally formulated on the basis of these drawings. For example, controls for emergency stop circuits, the formation of component groups belonging to a control or a network topology are developed on the basis of corresponding drawings. The development is carried out by manual implementation from the drawing, without special drawing elements having a semantics that can be used automatically for the specification of an automation solution. The implementation is rather manual or verbal. Relevant information that can be gathered from the drawing is often only partially transmitted. The information from the technical drawings cannot currently be used directly for the implementation of an automation solution.

The object of the invention is to enable a simplified, layout-oriented recording of requirements and specifications for an automation system and to provide the information in an electronically evaluable form. This object is achieved by a system for the layout-oriented acquisition of control-relevant information, with first means for graphically describing structures consisting of individual components, second means for graphically establishing at least one directional relationship between the components of the structures described and third means for specifying control-relevant information Interconnection of the components depending on the established relationships.

This object is further achieved by a method according to claim 1.

With this approach, control-relevant information is integrated graphically and interactively directly into technical drawings. The information is brought in by pre-defined or user-defined elements. Here, a procedural task is solved with the help of a drawing. A complex structure consisting of individual, for example physical, components is described using graphic means. The components are shown in their spatial arrangement. A physical layout, that is to say a description, for example of a conveyor, can be generated in this way. The components involved are then related to each other. This is also done graphically, for example by entering a material flow in the conveyor in the structure.

Depending on the directional relationship thus defined between the components of the complex structure involved, an interconnection, that is to say a control-relevant link, of the individual components is then specified or set up. Depending on their position within the complex structures and depending on the directed relationships to the neighboring elements the individual components are interconnected in this way in the overall system.

An advantage of using the system presented is the fact that the control behavior of individual components in connection with their environment can be recorded and specified using drawings. In this way, extracting control-relevant information from a drawing by a developer of an automation solution and then interpreting this information together with a subsequent implementation is superfluous. The relevant information results from the relationships established in the graphic between the individual components involved. This greatly simplifies and improves the specification of control behavior.

An advantageous embodiment of the invention is characterized in that the control-relevant information for recording is provided for an automation system of a process and / or manufacturing plant. Especially when designing complex industrial plants, it is important to design the most efficient design for the control technology and the associated control behavior of a plant. Drawings of a plant structure must be translated into control-relevant information. This can easily lead to a loss of information, or information in the drawing can be misinterpreted by the developer.

The system according to the invention now above all simplifies the acquisition of control-relevant information for such complex systems, since the system, after it has been designed graphically, can also be specified automatically in terms of its control behavior using the graphic. All components used in the system are shown in the graphic as

Represented elements and their behavior in the overall structure of the system can be described on the basis of the graphic that the integration of all elements in the control of the system can be specified precisely. The system according to the invention is particularly suitable for the design of complex control tasks.

A further advantageous embodiment of the invention is characterized in that the components in a library are designed as types with type-dependent properties and data interfaces. This training enables a developer to store certain, recurring elements, for example a system, in the library and to assign special properties to them. For example, a conveyor belt or a lifting table can be stored in the library. The user can then define properties that are typical for these elements and that occur again and again. Properties can be predefined, as well as freely configurable by a user. The characteristics and number of the required data interfaces of the individual components are also stored in the library in connection with the types. The data interfaces also have special properties that depend on the respective component. This embodiment of the invention makes it possible to store recurring objects in a prefabricated manner and thus reduces the effort involved in specifying an automation solution, since reusable modules can be used and the components already have predetermined interconnection options due to their special data interfaces, so that a developer can preselect possible ones Combinations can be presented. The use of the component library significantly reduces the effort required to generate an automation solution.

A further advantageous embodiment of the invention is characterized in that the interconnection of the components is provided via the data interfaces. Such an interconnection of the components via the data interfaces ensures that only those components can be selected that can also be connected to an existing component or its ports. The use of the data interfaces for the interconnection therefore specifies a selection of possible combinations, which greatly simplifies the specification of an automation solution for a developer.

A further advantageous embodiment of the invention is characterized in that the directional relationships between the components are established on the basis of a material flow in a process and / or manufacturing plant. In order to establish a predecessor / successor relationship of the elements involved that is essential for the control of a plant, the use of the material flow within a plant is an ideal solution, since an operator of the system is immediately aware of the spatial behavior of the material flow. It is not necessary to relate the individual components of the system to one another in an academic manner, but the simple graphical entry of the material flow in a drawing automatically establishes the important predecessor-successor relationship. The specification of an automation solution is enormously facilitated by this advantageous embodiment of the invention.

A further advantageous embodiment of the invention is characterized in that an information flow between the components opposite to the material flow is provided. A backward-directed information flow between the components involved, which is opposite to the material flow, advantageously guarantees a possibility of traceability within the system. A predecessor component knows at all times whether its successor component has sufficient absorption capacity for the material to be forwarded or whether the space for the next production piece is already free again. Manufacturing-related data can also be collected in a simple manner using this information flow and material tracking, which is, for example, in the This ensures a connection with a tracking system at the MES level (Manufacturing Execution Systems).

A further advantageous embodiment of the invention is characterized in that the directional relationships between data interfaces of adjacent components are established from the distance of the components from one another and the information available to the data interfaces. In this way, the spatial position of components in the graphical layout can advantageously be used for the construction or specification of the interconnection of the components with one another. The relationships between the data interfaces or ports of two or more adjacent components can be based on the geometric information, e.g. Position in the layout, together with a predefinable threshold value for the definition of the proximity of the components to one another required in the system or the layout and specific information about the ports are automatically derived. The port information here includes, for example, information on the type or

Direction of data flow (IN / OUT). If the corresponding information is available, a user of the system can establish the relationship and thus the connection in a simple manner by moving the components to one another on the surface of a screen, for example using a mouse.

A further advantageous embodiment of the invention is characterized in that type and / or instance and / or location information on the components is provided for use from the graphic layout. A specific description of the components used, such as lifting tables or conveyor belts, is already possible from the graphic layout. This information can then be used in an advantageous manner for the use of, for example, maintenance management systems. A maintenance information system can have a location information tion on a graphical basis. The information about the components involved does not have to be entered into such a system. The use of advanced information systems, such as plant information systems, is made significantly easier in this way and is also easier to implement financially.

A further advantageous embodiment of the invention is characterized in that fourth means are provided for the layout-oriented addition of further properties to components. This enables a developer to add additional attributes, for example via a separate input field on the user interface of the system, to the graphics of a special component. These properties can e.g. B. Functions such as "switch up" or "switch down" that are already added by the developer at the graphic level of a component. In this way, the automation-related behavior of the individual components is recorded more easily in the graphic layout and made available for the use of an automation solution.

A further advantageous embodiment of the invention is characterized in that a layout-oriented assembly of components into groups is provided. It is also advantageous that a layout-oriented assignment of superordinate semantics to the groups is provided. For example, several components may be related to a certain function. For example, there are so-called "emergency areas" that must be switched off uniformly. Likewise, several components can be assigned to a specific controller or several components can be assigned to a specific area in which a system for operator control and monitoring (O&M system or HMI, Human Machine Interface) is used. Merging components into groups makes it easier to assign them to a controller or an HMI, for example. The groups can overlap as desired. This means that a component can be assigned to a specific controller with other components, but it is visually represented with its data with other components on a B&B system. The groups can be assigned a uniform behavior in the form of a function. This training enables simple structuring of the system and simple mapping of the resulting automation solution. A continuous development of the entire automation concept of a plant is enormously simplified in this way.

A further advantageous embodiment of the invention is characterized in that an assignment of elements to limit permitted value ranges and / or attributes to components and / or functional groups and / or data interfaces is provided. The validity of relationships can be defined by inserting such "constraint elements" that can narrow or limit the possible interactions between data interfaces, components or functional groups. On the one hand, this enables the established relationships to be validated by automatically selecting only those components that can be connected to an existing component or its interfaces without violating the "constraints". On the other hand, information can be derived from this, such as whether the maximum number of port connections on a multi-port has been reached or whether, for example, the sum of the consumers exceeds the permissible maximum current. Through the introduction of virtual components with corresponding "constraints" it is also possible to introduce the boundary conditions to be observed. For example, a threshold can be defined for the maximum costs across all components used. A further advantageous embodiment of the invention is characterized in that a layout-oriented generation of a network configuration for communication of the components of a process and / or manufacturing plant is provided. If the individual components are related to each other and if higher-quality automation-relevant units have been defined on the basis of components combined into groups, the components involved can be directly networked at the graphic level. The network topology does not have to be specially developed. Rather, it results automatically from the position of the components and the relationships defined between the components. A simple conception and specification of the required network topology is possible in this way.

The invention is described and explained in more detail below on the basis of the exemplary embodiments illustrated in the figures.

Show it:

1 shows a schematic representation of the system for recording control-relevant information,

2 shows a schematic illustration of individual components with their directional relationships and properties,

3 shows a schematic representation of the graphic representation of a subsystem.

1 shows an exemplary embodiment of the system for the layout-oriented acquisition of control-relevant information. A first description 1 is used to create a graphic description in the system, for example a system consisting of individual components 21 _x .. _j . The components 21χ .. _j are selected from a set of components 21ι .. _n stored in a library 25. Here, the selected components 21 _j .. _{j are used} for the graphic description of the system structures 22, as a result of which a complex system can be compiled graphically. The second means 2 are used to graphically describe relationships 23 between the selected components 21ι..j so that they are stored in the layout. The specification of an interconnection 24 between the selected components 21ι, .j is generated by third means 3. The interconnection 24 takes place as a function of the directed relationships 23 via data interfaces 26. In this way, the components 21ι .. _{j are} related to one another in terms of data technology.

The advantage of the design of the system according to the invention shown in FIG. 1 is that parts of a system, here represented as a set of any components 21ι .. _n , can be graphically related to one another in a simple manner. Your data technology interfaces 26 can be linked to one another by defining directed relationships 23 on the basis of the layout and directly converted into control-relevant information.

The components have 2l _! .. _n each a unique identifier and type information. Any number of properties, so-called attributes, can be assigned to the components 21ι .. _n . In FIG. 2, the properties of the components 21 _ι .. _{n are represented} by symbols of different shapes. Properties or attributes of components 21ι .. _π can be both classic data types such as "integer" or "real", but it can also be structures such as "fields" or "arrays". Numbers of data interfaces 26, so-called ports, can also be assigned as attributes. It is also possible as attributes

Define links to other elements such as files or entries in other documents. A defined access interface (eg in the form of a DLL) can be assigned to a so-called link attribute. Such an access interface enables access to data in a referenced element, for example an Excel file. Components 21 Hilfe .. _n can be used to assign a semantics 32 using the attributes. A component 21i within a system can be assigned, for example, that it is a conveying element or a lifting table. An attribute can also be assigned a rule that describes how a certain attribute value can be derived from other attributes. In addition to the attributes, the components 21χ .. _n have any number of ports or data interfaces 26. Components that have ports or data interfaces 26 with the same structure can use them

Interfaces are interconnected. When building a port, the number and type of the respective attributes that describe the port are relevant. A connection direction in terms of In / Out can be assigned to individual attributes of a port or the entire port. This connection direction can be designed unidirectionally in the sense of an "either - or" if a conveying element has only one conveying direction. The connection can, however, also be bidirectional in the sense of “both as well” if a conveying element has two conveying directions (forwards / backwards; up / down). The port can be defined as IN and Out to allow both directions, or a graphic port as a representative is assigned a logical IN port and a logical OUT port. Multi-ports can also be defined that can be connected to more than one other port.

If the components 21] ... j selected for the description are assigned a direction using the second means for graphically establishing a directed relationship 23 such that each component 21ι receives a defined predecessor and a defined successor, the components 21ι involved can. .j are interconnected via their existing ports or data interfaces 26. Simply by arranging the components 21χ..j graphically, which already contain their control-relevant individual information in the form of their properties and their data interfaces 26. an automation solution can be specified. Here, the individual components 21ι .. _j are to be regarded as objects which, depending on their neighbors, shape certain properties in the overall system of the system. The information relevant for the specification of the control can thus be obtained directly from the position of the individual components 21a _. ..j can be seen in the graphic representation.

2 shows an exemplary embodiment of the invention, in which the relationships 23 between the selected components 21 _x ..j are established with the aid of a material flow 27. Here, the connection of ports or data interfaces 26 takes place in a graphic manner. A connecting line between the graphically represented ports is simply drawn along the material flow 27, as is planned in a plant. If a material flow 27 is used to establish the connection, the connection is automatically directed. The connection can also be made by simply placing the components 21ι .. _j accordingly, so that ports or data interfaces 26 to the

Neighboring elements or components 21ι..j are automatically constructed if the elements are at a defined distance from one another. An information flow 28 opposite to the material flow 27 is automatically established by the system. The information flow 28 runs along the established data interfaces 26 between the components 21ι..j.

Information about the components 21ι..j exists which describes the type of the respective component 21ι, but also its identity and its properties, for example the number of data interfaces 26 and their properties. Here, a component 21ι can also contain a further component 21i _{ι: L /} in the form of a property. This design enables components to be nested in such a way that components can consist of other components. For example, components such as control cabinets or racks can be implemented in the layout of the system. Accordingly, a higher-level component also has higher-level properties.

The graphic representatives of the components 21ι .. _n can, for example, be in 2D or 3D form and they have general properties of the components 21ι .. _n that they represent, ie they have a specific position, orientation, size and a specific form. In addition to type, identity and location 29, a number of further properties 30 can also be assigned to a component 21ι. These additional properties 30 can the components 2l _! .. _{n are} predefined so that they are available in the component library 25. However, properties can also be entered by the user at any time using special input windows and assigned to components 21ι .. _n .

The main advantage of the embodiment of the invention shown in FIG. 2 is that the individual elements or

Components 21 _x .. _j that make up a system can be easily related to each other. The components 21ι .. _j are either arranged graphically in such a way that they establish a connection to neighboring objects over a defined distance and an interconnection can take place on the basis of this spatial proximity. On the other hand, it is possible to implement the interconnection between the components 21ι..j by placing the components 21ι..j in a directional relationship 23 to one another by a user of the system, for example by entering a material flow 27, a unidirectional connection between the components involved 21 _a. .. _j builds up. A link between the components 21ι..j is then realized via the respective data interfaces 26 and a data transfer between the components 21ι..j is made possible. It is advantageous here that the material flow 27 is opposite to an information flow 28 between the components 21 _x ..j. This is advantageous, for example, if the material flow 27 within the plant is to be traced as part of an MES system. The opposite information flow 28 is essential for the smooth functioning of the components 21ι..j in the overall system. It ensures that a component 21ι knows the status of its successor component 21ι ₊ ι and whether, for example, a material can be passed on.

Each component is represented within the system as an object, which contains properties, such as type, identity, location 29, but also user-defined or function-dependent properties 30. The behavior of the respective components is thus already documented within the graphical representation in such a way that when the data interfaces 26 are linked, the control-relevant information of the individual components can be automatically recorded and related to one another. In this way, when the components 21 _L .J are joined together or the material flow 27 is entered, the control-relevant information is recorded and is advantageously available to the developer for the specification of an automation solution of the system shown graphically.

3 shows an exemplary embodiment of the system for the layout-oriented detection of control-relevant information, in which components 21 _x ..i are combined to form groups 31. A higher-level semantics 32 can be assigned to the groups 31. After the configuration of a system is completed graphically, a network configuration 33 can be established graphically with the aid of the system.

When the communication networks 33 are created, graphic relationships between the communication components, for example a Profibus, and the control components, for example a PLC. This structure takes place via data interfaces / ports 26 or their graphic representatives. The establishment is based on an information flow 28 or energy flow relationships. In addition to the material flow 27, any other information, energy or material flows can thus be recorded graphically and therefore also in terms of data technology within the framework of the system according to the invention.

FIG. 3 shows how components 21ι..ι can be combined to form functional groups 31. In the graphical representation, this is done by forming a selection set and selecting a functional group 31, for example in a tree view and performing a number of operations, for example adding / removing. In this way, components 21χ..i can be added to or removed from a group 31. Components 21χ..j, functional groups 31 and data interfaces 26 can be assigned so-called "constraint elements". These are elements that exert constraints in such a way that, for example, the validity of value ranges of individual characteristics or attributes is defined.

Assigning a higher-level semantics 32 (PLC area 32a, HMI area 32b) to specific groups 31 has the advantage that a set of components 21ι..ι can be assigned a higher-level property. For example, several components 21ι..ι can be combined in such a way that they are represented in the context of a B&B system 40 in order to be visualized on the system or the shop floor for an operator of the system 41. Likewise, components 21ι, .ι can be combined in order to assign them to a controller (PLC, PLC) 42. Special circuits can also be implemented, which represent, for example, an emergency on / off in the context of an "emergency area". Groups 31 can be put together as desired and a component 21 can be assigned to any number of groups 31. A higher-quality behavior of the components involved can thus be derived in a simple manner from the graphic layout and the automation-relevant information required for this is automatically made available. Likewise, a network topology 33 can be implemented in a simple manner. The design of the network to be specified results automatically from the relationships 23 of the components 21χ..j to one another. The question of which data connection is to be used, for example a bus system 33a or an Ethernet 33b, can already be specified in the graphic system on the basis of the information relevant to automation. Likewise, for example, the redundant design of data transmission devices can be designed based on the underlying information, since the layout clearly shows which areas of the designed system are safety-relevant and must therefore have a redundant data transmission device.

Overall, the grouping of the components 21ι..j shown in FIG. 3 into higher-value units simplifies the design of the automation solution of the system in a simple manner, since the higher-value units are each assigned a higher-level semantics 32, belonging to a controller or a B&B system, and structuring can be done graphically by the developer based on the system layout.

In summary, the invention relates to a system and a method for the graphic recording of system requirements and specifications in an electronically evaluable form. Elements of a system are represented graphically by selectable components 21. The components 21 are graphically brought into a relationship 23 to one another and a control-relevant interconnection 24 is automatically specified on the basis of the established relationship 23 and made available in electronic form.

Claims

claims

1. System for layout-oriented acquisition of control-relevant information, with - first means (1) for the graphic description of structures (22) .. _n consisting of individual (physical) components (21ι .. _n ), second means (2) for graphically establishing at least a directed relationship (23) between the components (21 _ι .. _j ) of the structures (22) described and third means (3) for specifying a control-relevant interconnection (24) of the components (21ι..j) depending on the established relationships (23).

2. System according to claim 1, so that the control-relevant information for recording is provided for an automation system of a process and / or manufacturing plant.

3. System according to claim 1 or 2, characterized in that the components (21ι .. _n ) in a library (25) are designed as types with type-dependent properties and data interfaces (26).

4. System according to any one of the preceding claims, characterized in that the interconnection (24) of the components (21 _x ..j) via the data interfaces (26) is provided.

5. System according to any one of the preceding claims, characterized in that the establishment of the directed relationships (23) between see the components (21ι..j) on the basis of a material flow (27) is provided in a process and / or manufacturing plant.

6. System according to claim 5, characterized in that a material flow (27) opposite information flow (28) between the components (21 _x .. _j ) is provided.

7. System according to one of claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t that the establishment of the directed relationships (23) see data interfaces (26) of adjacent components

(21ι..j) from the distance of the components (21ι..j) from each other and available information on the data interfaces

(26) is provided.

8. System according to any one of the preceding claims, characterized in that type and / or instance and / or location information (29) for the components (21 _ι ..j) are provided for use from the graphic layout.

9. System according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that fourth means (4) for the layout-oriented addition of further properties (30) to components (21ι..j) are provided.

10. System according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that a layout-oriented assembly of components (21ι..ι) into groups (31) is provided.

11. System according to claim 10, characterized in that a layout-oriented assignment of a superordinate semantics (32) to the groups (31) is provided.

12. System according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that an assignment of elements to limit permitted ranges of values and / or attributes to components 21ι..j and / or functional groups 31 and / or data interfaces 26 is provided.

13. System according to one of the preceding claims, characterized in that a layout-oriented generation of a network configuration (33) for communication of the components (21ι .. _m ) of a process and / or manufacturing plant is provided.

14. A method for the layout-oriented acquisition of information relevant to control, in which structures (22) consisting of individual (physical) components (21ι .. _n ) are graphically described, at least one directional relationship (23) between the components (21χ..j ) the structures (22) described are graphically established, a control-relevant interconnection (24) of the components (21 _x .. _j ) is specified depending on the established relationships (23).

15. The method as claimed in claim 14, so that the control-relevant information for an automation system of a process and / or production plant is acquired.

16. The method according to claim 14 or 15, characterized in that the components (21χ..j) in a library (25) are managed as types with type-dependent properties and data interfaces (26).

17. The method according to any one of claims 14 to 16, characterized in that the components (21 _x ..j) are interconnected via the data interfaces (26).

18. The method according to any one of claims 14 to 17, so that the directed relationships (23) between the components (21ι, .j) are established on the basis of a material flow (27) in a process and / or manufacturing plant.

19. The method as claimed in claim 18, so that an information flow (28) between the components (21χ..j) is opposite to the material flow (27).

20. The method according to any one of claims 14 to 16, characterized in that the directed relationships (23) between data interfaces (26) of adjacent components (21ι..j) from the distance of the components (21 _x ..j) from each other and existing information the data interfaces (26) are established.

21. The method according to any one of claims 14 to 20, characterized in that type and / or instances - and / or location information on the components (21χ .. _j ) from the graphic layout are used.

22. The method according to any one of claims 14 to 21, characterized in that further properties (30) to components (21ι..j) are added lay-out oriented.

23. The method according to any one of claims 14 to 22, d a d u r c h g e k e n n z e i c h n e t that components (21ι..ι) layout-oriented are assembled into groups (31).

24. The method as claimed in claim 23, so that a higher-level semantics (32) is assigned to the groups (31) in a layout-oriented manner.

25. The method according to any one of claims 14 to 24, characterized in that elements for restricting permitted value ranges and / or attributes to components 21 _x ..j and / or functional groups 31 and / or data interfaces 26 are assigned.

26. The method according to any one of claims 14 to 25, characterized in that a network configuration (33) for communication of the components (21ι .. _m ) of a process and / or manufacturing plant is generated layout-oriented.