WO1996019615A1

WO1996019615A1 - Process and device for detecting and influencing transversally given properties of paper webs

Info

Publication number: WO1996019615A1
Application number: PCT/DE1995/001791
Authority: WO
Inventors: Jürgen ADAMY; Clemens Graf
Original assignee: Siemens Aktiengesellschaft
Priority date: 1994-12-19
Filing date: 1995-12-14
Publication date: 1996-06-27
Also published as: EP0799348B1; ATE180026T1; FI972576A; FI972576A0; DE59505937D1; EP0799348A1

Abstract

In order to describe the quality of paper, different paper web properties, such as for example fibre orientation, formation, opacity, basis weight and shrinkage, are generally used, each of these properties being determined per se. According to the invention, at least the fibre orientation on the paper web is measured quantitatively continuously and used to control the transverse formation profile during operation of a paper-making machine. An associated arrangement is characterized by a fibre orientation control circuit (3).

Description

description

Method for recording and influencing the cross profiles of certain properties of paper webs and the associated arrangement

The invention relates to a method for detecting and influencing the cross profiles of certain properties of paper webs, such as in particular fiber orientation or formation, opacity, basis weight and / or shrinkage. In addition, the invention also relates to the associated arrangement for carrying out this method for use in paper machines.

Among other things, the uniformity of the paper properties across the production direction is decisive for the quality of paper. The location-dependent profiles of the paper properties transversely to the direction of production are called cross profiles. The monitoring and regulation of the paper properties require a measurement of these cross profiles.

The measurement of the cross profiles has so far been carried out individually for each property of the paper. The aim is to optimize the individual properties of the paper web independently of one another. According to the publication "Das Papier" (1993), no.

10A, p. V150 - V155, new types of actuators have been developed for this purpose, which make it possible to influence at least the cross-profile properties of the basis weight and fiber orientation independently of one another and intervene directly on the headbox.

In contrast, the object of the invention is to create further improvements and to provide an associated arrangement.

The object is achieved in that at least the fiber orientation is continuously quantitatively measured and used to regulate the cross profile of the fiber orientation over the paper web when operating a paper machine becomes. If necessary, in addition to the fiber orientation, formation, opacity, basis weight and / or shrinkage are measured at the same time and their transverse profiles are determined. For this purpose, a measuring head traversing the paper web is preferably used, which has an optical camera in addition to specific sensors. Such a camera is in particular a so-called CCD camera.

By means of a suitable evaluation method of continuous camera recordings of the paper web by means of a pattern recognition method or the like. a measured variable which is significant in particular for the fiber orientation of the paper web is now obtained, from which a control signal can be derived by comparison with a predetermined setpoint value profile. In contrast to the state of the art, complete fiber orientation cross profiles can be adjusted.

In the associated arrangement, in addition to the specified measuring head, in particular a control loop for fiber orientation is used to control the fiber orientation cross profile at the headbox of the paper machine. Such a formation control loop is preferably formed from a so-called formation controller, a unit for mapping the paper web, a control path and a unit with associated sensors.

Further details and advantages of the invention emerge from the following description of the figures of exemplary embodiments with reference to the drawing in conjunction with the further claims. They each show a schematic representation

1 is a top view of a paper web with an associated measuring head for measurement, FIG. 2 is a side view of the principle of a light transmission measurement with an additional light source, Figure 3 shows a diagram for defining the fiber orientation

Paper webs and the relevant measurand and Figure 4 is a block diagram of a formation control loop.

Some of the figures are described together.

In FIG. 1 and FIG. 2, 1 denotes a paper web with the width b, which moves from the headbox of a paper machine (not shown in detail in the figures) in the x direction as the paper running direction. The width b of the paper web 1 can be between 3 and 10 m and in particular be 5 m. The speed of the paper web in the x direction is, for example, 1500 m / min. A measuring head 10 is located on the paper web 1 at a distance without contact. All sensors for measuring the paper properties are spatially combined in the measuring head 10.

To detect cross profiles of certain properties of the paper web 1, the measuring head 10 is moved back and forth over the finished paper web 1 immediately before winding it up to form a coil. The measuring head 10 thus executes a movement traversing with time t. Because of the relative movement of the paper web 1 in the x-direction, the measuring head 10 covers a total zigzag path on the paper web 1.

The measuring head 10 usually contains a plurality of sensors known from the prior art, which are not dealt with in detail here. An optical camera 11 is specifically added to the sensors already present in the measuring head 10. A so-called CCD camera (charge coupled device) with electronic memories is advantageously used as the optical camera.

The camera 11 designed in this way enables simultaneous but independent measurement of the cross profiles of different paper properties, in particular of - fiber orientation

- formation

- opacity and basis weight

- shrinkage.

The properties indicated have the following meaning: The fiber orientation is essential for the degree of fiber crosslinking in the paper web. Since the fiber crosslinking determines the strength of the paper web 1, efforts are often made to achieve good fiber crosslinking on the one hand and a uniform one on the other hand. In certain cases, one would also like to give the fiber orientation a preferred direction in order to achieve certain mechanical properties. For this purpose, the fiber orientation must be recorded and influenced locally in detail on the paper web 1.

With an arrangement according to FIGS. 1 and 2, a usable measurement of the fiber orientation is achieved on the basis of a camera recording. This results in an image at the respective measuring point. The fiber orientation can be measured quantitatively by a suitable evaluation and, for example, an anisotropy factor can be defined.

FIG. 3 shows a measurement result for a paper web with a medium fiber orientation. The angle of the fiber orientation is plotted on the abscissa and the relative frequency is plotted on the ordinate. The angle of 90 ° points in the running direction of the machine (MR), the angles 0 and 180 ° point in the relevant transverse direction (QR) so perpendicular to it. The anisotropy factor is the ratio of the frequency in the machine direction MR to the frequency in the transverse direction QR. If the fiber orientation is the same for all angles, an anisotropy factor of 1 results. In the example in FIG. 3, the anisotropy factor is> 1, for example 1.5, which means that there is a preferred direction of the fiber orientation in the running direction of the paper web 1. In order to obtain a signal that can be used for control purposes, the fiber orientation must be measured continuously and quasi-continuously. The degree of fiber orientation and / or crosslinking is advantageously determined by a pattern recognition performed locally on the camera recording. Neural networks, for example, are suitable for this.

Formation, on the other hand, is the small-area, non-uniform distribution of the fiber mass in the paper web 1 with local accumulation or thinning. In practice, it can be assessed on the basis of a so-called cloudiness when looking through the paper in front of a brightly illuminated surface. The formation can thus also be detected optically, and there may be a connection with the fiber orientation.

The translucency of paper is referred to as opacity. It is determined by a light transmission measurement in which the intensity of the light that has passed through the paper is measured. For this measurement, a light source is attached to the camera 11 on the other paper side of the paper web 1. The latter can be seen in detail from FIG. 2 that the measuring head 10 traverses back and forth with the camera 11 and a unit 15 with a light source below the paper web 1 carries out corresponding traversing movements.

The weight per unit area is the mass per unit area of the paper web 1, this size being specified in g / m ² . The basis weight cross profile can also be translucent

Paper can also be determined by a light transmission measurement with the camera 11. Usually the absolute value of the basis weight is not recorded, but only the mean value-free course of the basis weight cross profile is reproduced on the basis of the fluctuations in brightness. The shrinkage inevitably results from paper production: in the drying area of the paper machine, water is removed from the paper pulp by passing the paper web 1 over metal rollers heated with steam. Drying can result in uneven shrinkage of the paper web 1 over its width b. If the actuators for basis weight and fiber orientation are in front of the drying section, the shrinkage undesirably changes the places of action of these actuators.

Controlling the fiber orientation cross profile on the paper web 1 requires knowledge of the assignment of each actuator to its place of action in the finished paper. This assignment is usually called "mapping". The traversing camera 11 can achieve an overall image across the entire width of the paper web 1. In the form of stochastic irregularities on the upper side of the paper web 1, the impression of regular screen markings is included.

In the publication "Das Papier" (1990), No. 10, pp. 529-537, a method for determining the cross-sectional shrinkage profile is described in detail: A two-dimensional fast Fourier transformation (FFT = fast fourier transformation) based on If the image points on the top of the paper are used, the spectral lines belonging to the screen markings are clearly provided. A back transformation of these spectral lines results in the noiseless sieve structure on the shrunk paper web 1. By comparison with the known geometry of the sieve markings, the shrinking cross profile is obtained. The shrinkage profile can e.g. used to do the mapping.

In the case of headboxes previously used, no independent regulation of the basis weight and fiber orientation profile is usually carried out. One limits itself to the regulation of the basis weight as the more important one two sizes. Due to increasing mechanical stresses when processing and using paper, the demand for a fiber orientation cross profile that is as uniform as possible and that can be adjusted to desired values has recently increased. In the case of the actuators for specifying the fiber orientation available in the publication mentioned at the beginning, the transverse profile is not regulated, but the individual actuators are set without direct feedback. This generally requires specific experience.

On the basis of the measuring head 10 with camera 11 described in detail with reference to FIG. 1 and FIG. 2, with suitably designed headboxes there is the possibility of influencing and correcting the precisely determined cross profiles independently of one another. Suitable actuators can now be used for specifying the fiber orientation cross profile, which is measured in accordance with FIGS. 1 and 2 and evaluated online by pattern recognition. The presence of actuators and sensors therefore enables this

Setup of a control device of the relevant cross-profile for practical use in paper machines.

In FIG. 4, a complete control circuit 3 for fiber orientation consists in detail of a fiber orientation controller 31, a mapping unit 32, an actuator 33, a controlled system 34 and a sensor unit 35. These units are each only schematic ("black boxes") shown, the signal feedback to the comparison point 30.

Due to the continuous measurement of the fiber orientation, a feedback of the determined cross-profile signals and connection to a controller comparison point 30 is possible. The mapping function of the unit 32 also takes into account the change in the assignment of the actuator 33 to the relevant actuator effect caused by shrinkage. Overall, the possibility of influencing the fiber orientation already suggested in the other context can thus be supplemented by the specified quantitative measurement of the fiber orientation to build up a complete control system. In the same way, the other significant properties of paper webs, such as formation, opacity and basis weight, can be incorporated into the control process, taking shrinkage into account.

Claims

claims

1. A method for detecting and influencing cross profiles of certain properties of paper webs, such as in particular fiber orientation or formation, opacity, basis weight and shrinkage, characterized in that at least the fiber orientation of the paper web is continuously quantitatively measured and for regulating the cross profile of the fiber orientation over the paper web during operation be used in a paper machine.

2. The method of claim 1, d a d u r c h g e k e n n ¬ z e i c h n e t that in addition to the fiber orientation, formation, opacity, basis weight and shrinkage of the paper web are measured simultaneously and their cross profiles are determined

3. The method of claim 1 or claim 2, d a d u r c h g e k e n e z e i c h n e t that a traversing over the paper web measuring head is used, which besides specific sensors see an optical camera.

4. The method of claim 3, d a d u r c h g e k e n n z e i c h n e t that a so-called. CCD camera is used as a camera.

5. The method according to claim 1 or 2, dadurchge ¬ indicates that for quantitative measurement of the fiber orientation or formation, a pattern recognition ^'of the camera recordings is carried out.

6. The method of claim 5, d a d u r c h g e k e n n z e i c h n e t that the pattern recognition takes place by means of neural networks.

7. The method according to claim 6, dadurchgekenn¬ characterized in that the control intervention takes place on the headbox of the paper machine.

8. The method according to any 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 mutually independent influencing of the cross profiles of fiber orientation on the one hand and basis weight on the other hand follows.

9. The method according to claim 7 and 8, d a d u r c h g e ¬ k e n n z e i c h n e t that an actuator for influencing the formation is used as an actuator for the fiber orientation.

10. Arrangement for performing the method according to claim 1 or one of claims 2 to 9 for use in paper machines, characterized by a Regel¬ circuit (3) for the fiber orientation for controlling the Quer¬ profile of the fiber orientation at the headbox of the paper machine .

11. The arrangement according to claim 10, dadurchge ¬ indicates that the control loop (3) from a controller (31) for fiber orientation, a unit (32) for mapping the paper web (1), an actuator (33), a controlled system (34) and a unit with associated sensors (35).

12. The arrangement according to claim 11, dadurchge ¬ indicates that fiber orientation controller (31), mapping unit (32), actuator (33), controlled system (34) and sensors (35) are connected in series and that their output signal to the controller comparison point (30) of the control loop (3) is fed back.