EP0946312A1

EP0946312A1 - Method for automatic conducting of a straightening process

Info

Publication number: EP0946312A1
Application number: EP97953842A
Authority: EP
Inventors: Wilhelm Guericke; Marcus Paech; Eckehard Albert
Original assignee: Witels Apparate-Maschinen Albert & Co KG GmbH
Current assignee: Witels Apparate-Maschinen Albert & Co KG GmbH
Priority date: 1996-12-20
Filing date: 1997-12-17
Publication date: 1999-10-06
Anticipated expiration: 2017-12-17
Also published as: US6438442B1; WO1998028098A1; JP2001506544A; DE19653569C2; DE59703697D1; DE19653569A1; EP0946312B1; DK0946312T3; BR9713605A; AU5759398A; ES2159895T3; CA2275334A1

Abstract

The invention relates to a method for the automatic conducting of a straightening process for an object that is to be straightened, such as sheet metal, strips, sections, pipes, and in particular for wire-like or multiwire-like objects that are to be straightened, in a straightening device or a levelling machine with at least one mangle roll which can be adjusted by an actuator. In accordance with the invention, a process simulation model of a straightening process that is to be conducted, and a process simulation programme are set up, and the latter gives directly "online" the settings of the adjustable mangle roll(s). During the straightening process, changes in the product data, in particular the material characteristics and/or dimensions of the object to be straightened which influence the realization of the straightening process, are recorded, and from these, data for setting the adjustable mangle roll(s) are also calculated, and signals are emitted for the automatic setting of the adjustable mangle roll(s) by means of an actuator and/or actuators.

Description

Process for automated process control of a straightening process

The invention relates to a method for the automated guidance of a straightening process for a straightening good, such as sheets, strips, profiles, tubes and in particular for a wire or multi-wire shaped straightening good in a straightening apparatus or in a straightening machine with at least one straightening roller adjustable by an actuator.

Non-rotating roller straighteners or straighteners are used to remove curvatures from straightening goods. By adjusting the straightening rollers, which are mutually offset in two rows, relative to one another, in at least one straightening plane, the straightening material experiences changing bends during its passage. These alternate bends should be of such a number and size that the inlet curvatures of the leveling material are eliminated over the entire length of the leveling material.

Given the number of change bends, the size of the change bends is adjusted more or less intuitively based on the experience of the straightening machine based on the experience of the operator. The settings of the individual straightening rolls are changed under visual contact with the outgoing straightening material until a satisfactory straightness is achieved. A non-rotating straightening device for bending machines with an integrated measuring device is known from DE 195 03 850 C1. In the straightening apparatus, at least one material bending measuring device is arranged in the direction of flow of the material behind at least one straightening unit, in which at least one measuring section is provided for a length of material that is predetermined in length, with at least one mechanical and / or electronic measuring the extent of the bending and the sense of bending along the measuring section and / or an optical scanning device is arranged, with the scanning device generating signals representing the measured bending of the material section, with which an actuator is adjusted accordingly.

The measuring device of the known straightening apparatus works on the principle of determining the curvature according to the three-point method, which is only used for cut-to-length straightening goods or for stopped straightening goods, i.e. H. if the target is free of external forces and moments, neglecting gravity, gives correct results. If the curvature of the straightening material to be discharged is not constant over the length of the measuring section, the measurement result is also influenced by the length of the measuring section.

The straightening process is interrupted by the necessary stopping of the straightening goods. Stopping and restarting influences the result of the curvature measurements and causes changes that affect the quality of the straightening process. This means that the setting can only be checked by stopping the straightening device again, ie continuous monitoring and regulation while the straightening material is running or during straightening is not possible. The object of the invention is to provide a method which practically enables instantaneous, automatic adjustment of the setting of at least one straightening roller of a straightening apparatus or a straightening machine to continuously measured data of the respective straightening good without stopping the straightening process.

This object is achieved by a method with the features of claim 1. Advantageous embodiments of the invention can be found in the subclaims.

The invention is summarized, including advantageous embodiments, the principle of modeling the straightening process to be automated using mathematical-physical laws in a preparatory phase, creating a simulation program and using the simulation program to perform a variation calculation with variation of the product data, in particular the material properties and / or the dimensions of the target. This phase can be regarded as "offline". On the basis of continuously measured product and / or process data during the ongoing straightening process, ie without stopping the straightening goods, the settings required to achieve the desired product quality are made very quickly, including the results of the variation calculation "online" of the straightener or straightener. The change in the setting is objective and determined. The measured product and / or process data are also used to check the model created and the simulation program and, if necessary, to change it. Instead of subjective experience, the sense of proportion of the objectivity occurs when the straightener or the straightener is operated. This not only simplifies the process and carries it out automatically, it also increases the quality.

The invention is explained in more detail below with reference to two diagrams.

Diagram 1 shows an embodiment of the automated process control according to the invention.

In the preparation phase I, a process simulation program A, with which the straightening process to be automated can be virtually simulated, is created and used. In the process simulation program A, machine data B, technological process data C of the intended straightening process, material data D of the straightening good and the desired quality S (straightness or flatness, residual stress state over the straightening material cross section, material properties, e.g. a desired yield point and / or an influence on the pronounced yield point) of the straightened product.

The process simulation program A is subject to a variation calculation F, in which parameters, for example the geometric dimensions and / or the yield strength of the material to be straightened, are varied. The parameters are preferably varied, to the change of which the straightening apparatus or straightening machine E should react automatically. The parameter variations are to be matched to the specifics of the respective straightening process and / or the straightening apparatus or the straightening machine E. Results of the variation calculation F are product and / or process data and those for Automation necessary target values, ie the necessary employment (s) of the standard role (s) to achieve the desired quality. All calculation results of the variation calculation F are stored in a database H in the form of relationship matrices G.

In the implementation phase II, a process calculation model J is provided, which uses the relationship matrices G and thus the relationships between the influencing variables and the target variables of the straightening process created in preparation phase I and depending on the recorded production data O from the higher-level material flow or the material tracking system ( MVS) P performs the relationship matrix selection K and the corresponding call. On this basis, the process calculation model J realizes the calculation and output of the target values, taking into account product and / or process data M determined by measurement technology. H. the setpoint L with the help of methods of assessing statistics. For the basic automation N, these target values correspond to the target values Sw. The current actual values Iw are compared with the target values Sw, the deviations being used to match the two values. The product and / or process data M determined by measurement technology are stored in the form H in the database H. You can contribute to the optimization R of the process simulation model and the process simulation program A in a subsequent preparation phase.

A corresponding implementation phase II consists of several operators. In addition to an operator for setting or automatically correcting the setting values, there is also an operator for basic setting of the Straighteners or the straightening machine immediately before the start of production as well as an operator for measuring value implementation. Before the straightening material is brought in, a thickness measurement is carried out, e.g. B. with the help of laser distance sensors. The thickness value is transferred to the operator of the job. At the same time, a value for the yield point of the leveling material is received, which either comes from the higher-level material flow or material tracking system P or is determined with the aid of the yield point operator. For this purpose, the yield point operator uses the information content of a relationship matrix G selected and retrieved from the database H and measurement results of the process variable directivity. The yield point determined by the yield point operator is checked for plausibility. The operator of the job can transfer the job setpoints to the basic automation N with the information on the thickness and yield strength of the target material using selected and retrieved relationship matrices G. This means that the settings of the leveling roller (s) derived in this way take into account the respective thickness and the yield strength of the leveling material. In this way, the quality of the target material can be guaranteed to be constant regardless of fluctuations in these two parameters.

In addition to the straightening force, the invention also makes it possible to use other process parameters for automation and / or to react to fluctuations in other straightening material parameters. For example, the shape curve of the leveling material can be measured in a leveling device or a leveling machine and compared with a simulated shape curve. The results of the comparison make it possible to make detailed statements about the straightening good or the state of the straightening process. There are also several options for organizing litigation, which are dependent on the frequency of the change in the properties of the target, which can change, for example, from batch to batch, from target to target and / or over the length of the target.

By separating the preparation phase I from the implementation phase II, straightening processes that run very quickly can also be automated. The described automated management of a straightening process is general and time-critical.

The solution shown in diagram 2 has units or values corresponding to the letters in diagram 1, which are therefore not explained further. Here, the process simulation program A, which takes into account the metrologically determined product and / or process data M and the acquired production data O, directly passes on the target values L to the basic automation N.

Claims

claims

1.Procedure for the automated guidance of a straightening process for a straightening good, such as sheets, strips, profiles, tubes and in particular for wire or multi-wire shaped straightening good in a straightening apparatus or a straightening machine with at least one straightening roller adjustable by an actuator, according to which a process simulation model of a straightening process to be carried out and A process simulation program is created and the latter directly "online" specifies the settings of the adjustable straightening roller (s), changes in the product data during the straightening process, in particular the material properties and / or dimensions of the respective straightening material influencing the design of the straightening process, and also data from this for setting the straightening process adjustable straightening roller (s) are calculated and signals for automatic adjustment of the adjustable straightening roller (s) are output by means of an actuator or actuators.

2. The method according to claim 1, characterized in that the process simulation model and the process simulation program are created in a preparation step.

3. The method according to claim 2, characterized in that simulation calculations are carried out and the results are incorporated into a process calculation model that on this basis specifies the settings of the adjustable straightening roller (s).

4. The method according to any one of claims 1 to 3, characterized in that with the process simulation program on the basis of the process simulation model, simulation calculations are carried out, the results of which are stored and / or are incorporated into the process calculation model.

5. The method according to any one of claims 1 to 4, characterized in that the process simulation model and the process simulation program are optimized by the measurement data acquired during the straightening process.

6. The method according to any one of claims 1 to 5, characterized in that the residual stress state is calculated via the straightening material cross section.

7. The method according to any one of claims 1 to 6, characterized in that the yield strength of the respective straightening good is determined continuously in dependence on the respective product and process data.

8. The method according to any one of claims 1 to 7, characterized in that the pronounced yield point (Lüders range) is calculated, reduced or eliminated for ferrous metals.

9. The method according to any one of claims 1 to 8, characterized in that the virtual images of the straightening process with the process simulation model and the process simulation program using data on the straightening apparatus or the straightening machine, about the desired technological processes, about the geometric dimensions and material properties and about the desired quality of the target material.

10. The method according to claim 9, characterized in that the respective shape of the incoming straightening good in the straightening apparatus or in the straightening machine is detected as geometric dimensions.

1 1. The method according to any one of claims 1 to 10, characterized in that each process simulation program is subjected to a variation calculation.

12. The method according to claim 1 1, characterized in that at least one relationship matrix is created by each process simulation program subjected to a variation calculation.