DE4203432A1 - Object orientated monitoring of process control variables - using object oriented database contg. objects in $ABSTRACTDhierarchial order w.r.t. information, and performing validation cascade - Google Patents

Abstract

The monitoring method involves acquiring and evaluating process parameters in an ordered object (01, 02,..06) of an object oriented database. Some objects corresponding to a process parameter (MZ1, MZ2, ME1,...ME4) contain additional information on the parameter, at least construction rule (B), validity (G), valid life (D) and remaining valid life (R). The objects are ordered in a hierarchy where the lowest level (04, 05, 06) contain direct parameters (ME2, ME3, ME4) and higher levels contain direct (ME1) or constructed values (MZ1, MZ2). On acquisition of new values and on refreshment of constructed values, the validity of values in the system is constantly maintained. ADVANTAGE - Parameters are stored in real time.

Description

The invention relates to a method for monitoring technical Processes or technical systems.

The automation of technical processes or systems requires among other things, the automatic monitoring of a variety of Process or plant parameters. This happens with process computers that read in and save the parameters. In the case an automatic process or system control Parameters also evaluated by the process computer; it will Conclusions about the current process or plant was hit and corresponding control commands generated. The Monitoring and evaluation of the parameters has to do in real time happen; it must be ensured that between the occurrence of a particular incident and a subsequent one Control intervention the case-specific, maximum Response times must not be exceeded. Furthermore it is necessary that the representation of the process to be controlled or the system to be controlled is possible due to the parameters used is as comprehensive and consistent as possible, so that all essential Incidents are recognized safely and early.

The invention is therefore based on the object of a method specify with the parameter technical processes or techni systems, fed consistently and in real time can be saved.

This is done according to the invention with a method for Monitoring of technical processes or technical plants according to claim 1.  

Object-oriented databases - such as in time publication "Informationstechnik it 32 (1990) 5" 1, pages 343 ff, described - are particularly advantageous for modeling complex issues of any kind. Conventional objects However, databases are only for static tasks and not for use in rapidly changing circumstances as in process and plant automation technology prevail, suitable. This is within the scope of the invention a dynamic update of the individual objects of the Da depending on the temporal changes of the Process or the plant encountered. The invention is thereby especially for use in monitoring complex technical Processes or technical systems.

The advantages of the invention are particularly evident in an application of the method for controlling a technical Process or a technical system according to claim 2, because the quality of a control system essentially depends on the quality of the Actual value acquisition depends.

The invention is illustrated by three figures.

The following are examples:

Fig. 1 shows the structure of an object-oriented database and

Fig. 2 shows an exemplary circuit arrangement

Fig. 3 shows the structure of a program running on a process computer control software for an industrial process.

The structure of an object-oriented database according to the invention shown in Fig. 1 comprises 6 objects O1, O2, ... O6, which are hierarchically arranged in three database levels, the first level by the first object O1, the second level by the second and third object O2, O3 and the third level is formed by the fourth, fifth and sixth objects O4, O5, O6. Each object contains either a simple process parameter ME1, ME2, ME3, ME4 or a composite process parameter MZ1, MZ2. Furthermore, each object contains additional information about the respective process parameter, namely the educational regulation B, period of validity D, remaining period of validity R and validity G.

The functioning of the database according to the invention is explained using the exemplary circuit arrangement shown in FIG. 2.

The circuit arrangement of Fig. 2 consists of a parallel circuit of three resistors R1, R2, R3. Each of these resistors R1, R2, R3, a current meter is connected in series. The total current I _G flowing through this circuit arrangement results from the sum of the individual currents I ₁ , I ₂ , I ₃ measured by means of the current measuring devices.

In addition to the three current measuring devices, a voltage measuring device is also provided, by means of which the common voltage U applied to the resistors R1, R2, R3 is measured. By voltage U and total current I _G , the total power consumption of the circuit is in accordance
P = U · I _G determined.

When monitoring the circuit arrangement according to FIG. 2 by means of the object-oriented database according to the invention according to FIG. 1, the three objects O4, O5, O6 of the lowest database level each contain a measured value of the three individual currents I1, I2, I3 of the circuit arrangement. The formation rule B is 1 in the case of a simple process parameter, ie the read measured values of the individual currents I1, I2, I3 are stored in the objects O4, O5, O6 as process parameters ME2, ME3, ME4. This also applies to the second object O3 of the second database level, in which the voltage U of the circuit arrangement is stored as a simple process parameter ME1.

The other objects O1, O2 of the database each contain composite process parameters MZ1, MZ2, namely the total current I _G in the first object O2 of the second database level as process parameter MZ2 and the total power consumption of the circuit arrangement in object O1 of the top database level as parameters MZ1. The instruction B for the second composite process parameter is MZ2
I _G = I ₁ + I ₂ + I ₃ ,
and for the first process parameter MZ1
P = UI _G.

The essential parameters of the circuit arrangement, such as voltage U, current consumption I _G , I ₁ , I ₂ , I ₃ and power loss P are thus recorded in objects O1, O2, ... O6 in the database. By querying the individual objects, the desired information about the circuit arrangement can thus be obtained at any time.

However, topicality for this is topicality of the stored process parameters, which ensures this is that the measured simple process parameters ME1, ME2, ME3, ME4 read in at regular intervals and the whole Database system with every change of a process parameter or its validity G is updated. Furthermore, it is necessary dig that even for the fault, which consists in the fact that a Process parameters ME1,. . . ME4 is not read in or is read in too late, Precaution is taken. This is used in the invention object-oriented database the additional information that each Contains object via the respective process parameter. This um in addition to the educational regulation B already described the period of validity D, the remaining period of validity R and the Validity G.  

The period of validity D indicates how long the associated process parameter is valid after each update. In order According to the operation of the database, the period between two updates of an object may be less than the Gül Duration of activity D. This is specified in the task-specific Er position of the database and during operation not changed. The period of validity D of a process parameter is especially in chemical processes or in the um global technology of importance. For example, the quality of drinking water at specified intervals by corresponding appropriate analyzes are checked.

In contrast to the validity period D, the remaining time of the Validity R with every update of the associated process parameters set to the value of validity D and in from Database system predetermined intervals decreased until the Value 0 is reached, or a new update of the associated process parameter has taken place. Reaches that Remaining time of validity R is 0, the corresponding one Process parameters are invalid and the validity G is invalid set. The user then learns when accessing this Object or by an alarm triggered by the database, that the process parameter contained therein is not up to date and therefore does not have to be right.

If a process parameter becomes invalid, the dependent process parameters also become invalid. In the specific case, in the event of an invalid second simple process parameter ME2 in the first object O4 of the lowest database level, the composite process parameters MZ1, MZ2 dependent thereon in the first and second objects O1, O2 also become invalid. In Fig. 1, this dependency is represented by arrows between the objects.

In addition to the validity / invalidity of an object any change in the value of the process parameter to the parent passed objects. The stored in these objects  th composite process parameters are according to their Bil Regulation B newly determined, and the remaining validity speed R becomes the smallest value of the remaining times of validity of the objects included in the educational regulation.

This is the case with the object-oriented database according to the invention with a clear and consistent representation at all times given a process or a plant. Continue on occurring errors detected, the necessary steps from the database system itself and the user of the error risk exempted from the task, the effects of a non-updating The measured value must be taken into account in individual cases.

Fig. 3 shows the structure of a system for controlling a real-time process. This structure includes the object-oriented database OD, the database control DBS, the complex of application software AS and the process P to be controlled.

The object-oriented database OD has the structure described with reference to FIG. 1. The database control DBS comprises a timer ZG, an action trigger AA and an update unit AK. The connection between the timer ZG and the object-oriented database OD is provided via a clock line T. Another connection exists between the update unit AK and the object-oriented database OD via an update connection A and a data connection DEA. The application software AS, which solves the control tasks of the process P, is also connected to the process itself and the database system DBS via data lines and lines for triggering the action.

The system works as follows:

The process parameters describing process P are either determined directly by measurement (simple process parameters) or derived from the directly determined, simple process parameters  tet (composite process parameters). Deriving one too Compound process parameters happens, as already described ben, according to the associated educational regulation, which together with the process parameter in an object of the object-oriented data tenbank is included.

The measurement of the simple process parameters is controlled through the application software AS. The measurement results are in transfer the object-oriented database OD and there in the corresponding objects saved.

After each entry of the measured value of a simple process parameter, the database is updated, ie the composite process parameters dependent on the newly entered, simple process parameters are newly determined. The additional information is also updated, as has already been described with reference to FIG. 1. The update is controlled by the update unit AK of the database control DBS.

Other essential function modules of the database control DBS are the timer ZG and the action trigger AA.

The timer ZG controls the reduction in the remaining time of the slurry activity R. The action trigger AA monitors the validity G all database objects. An "invalid" state of an object is passed on to the application software AS, which then ent speaking measures, such as an error message or triggers an automatic measurement query.

The structure of a system shown in FIG. 3 is advantageous due to the clear structure when using the method according to the invention, but it is not absolutely necessary. In addition to the wide range of possible uses, the invention therefore also enables the user to use a variety of advantageous configurations.

Claims (2)

1. Method for monitoring technical processes or technical plants by recording and evaluating selected process or plant parameters, in which the evaluated process or plant parameters are each stored in an assigned object (O1, O2, ... O6) of an object-oriented database , whereby at least some of the objects contain, in addition to a process or system parameter (MZ1, MZ2, ME1, ... ME4), additional information about them, which includes at least the educational regulation (B), validity (G), validity period (D) and remaining time of validity (R), in which the objects (O1, O2, ... O6) of the database are hierarchically arranged and the lowest level of objects (O4, O5, O6) read in simple process or system parameters (ME2 , ME3, ME4) and the objects of the higher levels (O1, O2, O3) contain either simple (ME1) or composite (MZ1, MZ2) process or system parameters, which consist of process or system parameters of the respective s subordinate level can be derived according to the given educational regulation (B), with the following procedural steps:

• - The simple process or system parameters supplied to the database (ME1, ... ME4) are stored in the associated objects (O3, O4, O5, O6);
• - With the adoption of a process or system parameter (ME1, ... ME4) by an object (O3, O4, O5, O6), the additional information (G, R) is also updated;
• - Each change of an object is passed on to the higher-level object (s) (O2, O1), whose instruction (B) contains the changed object, up to the highest level and the composite process or system parameters (MZ1, MZ2) contained in the objects ) and the additional information (G, R) are updated;
• - The value of the remaining time of validity (R) of all valid objects (O1, O2, ... O6) is reduced by a constant amount at regular intervals;
• - The object and all dependent superordinate objects are declared invalid if the remaining time (R) of an object has the value zero;
• - after the arrival of a new simple process or plant parameter (ME1, ... ME4), an invalid object is declared valid again, the value of the remaining period of validity (R), the amount of the validity period (D) is entered, and the changes are passed on to the superordinate object (s) whose educational instruction (B) contains the modified object.

2. The method according to claim 1, characterized records that the stored process or equipment parameters (MZ1, MZ2, ME1,... ME4) as actual process or system values to control a technical process or a technical system can be used.