DE102020103019A1 - Process for self-monitoring of a process engineering process - Google Patents

Abstract

The invention relates to a method for self-monitoring of a procedural process, wherein a pressure measuring device is provided for determining the pressure situation of a flowable medium in a pipeline and wherein the pressure measuring device has a signal processing unit with a microcontroller that provides an output signal for a control unit for monitoring and controlling the process In order to reduce the maintenance or calibration effort of the actuators, filters and seals involved in a process system, the invention proposes that the time course of the prevailing pressure situation be evaluated in the microcontroller and that the cases are counted in which the pressure change Δp is greater than a limit value g in a time interval Δt in relation to a system parameter G.

Description

The invention relates to a method for self-monitoring a process engineering process according to the preamble of claim 1.

In today's process and process engineering, process parameters such as temperature, pressure and flow or flow are measured in a variety of forms and used for process control and regulation. For reasons of product and process quality as well as operational reliability, reliable and long-term stable detection of these process parameters with known measurement error limits is becoming increasingly important.

Due to the process, there may be excessive fluctuations in these process parameters, which is particularly severe for the sensors and measuring devices monitoring the process, but also for the entire system. In addition to the actual amounts of these excessive fluctuations in the process parameters, the number of cases in which the entire system is exposed to excessive conditions and the duration of these excessive conditions are decisive for the general “health” of the system.

The consequence of excessive conditions is material fatigue and increased wear of the sensors and actuators involved in the process, such as pumps and valves, but also filters and seals. For this reason, regular, often preventive maintenance, calibration and / or adjustment is usually carried out for the sensors and actuators concerned. The time interval between two calibrations or the maintenance intervals depends on the permitted tolerance band and the operating conditions of the sensor or actuator. It is chosen based on empirical values so that there is a high probability that the tolerance band will not be left between two consecutive calibrations or maintenance.

In many systems it is possible to install attenuators in order to limit these excessive conditions spatially and thus to protect the sensors and actuators from such rashes. However, these measures cannot always be used or have to be temporarily suspended, e.g. during the start of the process, during cleaning in hygienic systems or basically with abrasive media, e.g. Sludges. In these cases, the previously mentioned preventive maintenance, calibration and / or adjustment must be used.

Every maintenance, adjustment or calibration is associated with considerable effort and costs, since the sensor must be removed (system downtime, dismantling of system parts).

The object of the invention is to reduce the calibration and maintenance effort of the sensors and actuators involved in a process plant.

This object is achieved according to the invention by a method having the features of claim 1. Advantageous refinements of the invention are specified in the subclaims.

The focus of the invention is on processes with a flowing medium, so that the entire process system can include not only sensors but also a large number of actuators, for example valves, flaps and the like, and filters and seals. The general condition of the system depends largely on the functionality of these actuators, filters and seals, which is influenced by aging-related drift and degradation effects.

Against this background, it is the essence of the invention to monitor the state of the system by means of a pressure measuring device. Capacitive measuring devices working with strain gauges or piezo elements are particularly suitable as pressure measuring devices. All of these measuring principles have been known for many years. With the help of the information recorded by this measuring device and passed on to a signal processing unit, a predictive diagnosis with regard to maintenance or calibration of the sensors, actuators, filters and seals involved in the process system can now be derived. For this purpose, two factors that are essential for the stress on these devices and elements are evaluated: the number of very rapid pressure changes and the reaching or exceeding of particularly high pressure values.

The invention is explained in more detail below using an exemplary embodiment with reference to the drawing.

1 shows an example of the graphical representation of a pressure curve over time, wherein in 1 an event-oriented consideration of the general stress of the process plant takes place.

A pressure measuring device continuously records the pressure prevailing in the system. These measured values are evaluated with regard to their change and the associated speed of the pressure changes is determined. In 1 certain events are marked by thick lines, which should be used for the evaluation with regard to the speed of the pressure changes as an essential influencing factor for the hydraulic loading of the process plant. This refers to events in which a very rapid change in pressure has occurred. The lower and upper limits of the permissible pressure range are identified with ASP and AEP. The quotient of this permissible pressure range and a system-specific rise time t _s is referred to below as system parameter G. The rise time t _s is a specific time in which the flow increases from zero to its nominal value. It can differ from system type to system type. With the same systems, however, their value is typically the same.

The pressure change Δp in a time interval Δt in relation to the mentioned system parameter G is decisive for the hydraulic load. The sum of events in which this ratio is greater than a predetermined limit value g suggests an expected maintenance effort. Advantageously, g corresponds to a value> 0.1, in particular> 0.12, and the summation of the events is carried out by a microcontroller as part of the electronic signal processing unit of the pressure measuring device.

The calculation in the microcontroller can be summarized as follows: $$HydrauliscHeAnlaGenbeansprucHunG={\displaystyle \sum _{>G}\frac{\raisebox{1ex}{$\mathrm{\Delta }p$}\!\left/ \!\raisebox{-1ex}{$\mathrm{\Delta }t$}\right.}{G}}={\displaystyle \sum _{>G}\frac{\raisebox{1ex}{$\mathrm{\Delta }p$}\!\left/ \!\raisebox{-1ex}{$\mathrm{\Delta }t$}\right.}{\frac{AEP-ASP}{ts}}}$$

A typical value for the pressure change is, for example, 50 bar with a rise time t _s of 1 millisecond. Every event in which the abovementioned quotient reaches a predetermined threshold value g is registered by the microcontroller and stored in total. When this sum has reached a certain value, the user is informed that maintenance or calibration of the entire process system should be carried out in order to avoid measurement errors.

Claims (3)

Method for self-monitoring a process engineering process, a pressure measuring device being provided for determining the pressure situation of a flowable medium in a pipeline, and the pressure measuring device having a signal processing unit with a microcontroller, which provides an output signal for a control unit for monitoring and controlling the process, characterized in that the temporal course of the prevailing pressure situation is evaluated in the microcontroller and the cases are counted in which the pressure change Δp in a time interval Δt in relation to a system parameter G is greater than a limit value g, the calculation being carried out according to the following formula : $${\displaystyle \sum _{>G}\frac{\raisebox{1ex}{$\mathrm{\Delta }p$}\!\left/ \!\raisebox{-1ex}{$\mathrm{\Delta }t$}\right.}{G}}$$

and the system parameter G is formed from the quotient of the difference between a system-specific upper and lower permissible flow range and a system-specific rise time t _s . Procedure according to Claim 1 , characterized in that the duration of the time in which the pressure value has reached an upper threshold value is also recorded. Procedure according to Claim 2 , characterized in that in addition the level of the threshold violation is evaluated.

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