DE29920463U1 - Roll winding device - Google Patents

Description

DR.-ING. ULRICH KNOBLAUCI DR.-ING. ANDREAS KNOBLAUCH _6O3 2o Frankfurt/Main _{19 Nov} 1999

PATENT ATTORNEYS Kühhornshofweg 10

TELEPHONE: (069) 956 2030 TELEPHONE: (069) 563002

VAT ID/VAT: DE 112&Ogr;1214&THgr;

KW 3 65 GM

VOITH SULZER PAPER TECHNOLOGY PATENT GMBH D-8 9522 HEIDENHEIM

Roll winding device

The invention relates to a roll winding device with at least one roller, which forms a support surface for a winding roll, and with a determining device for determining a roll diameter of the winding roll.

Such roll winding devices are used to wind a material web, which may have been cut into longitudinal strips, into winding rolls. The invention is described below using a paper web as an example of a material web, but is not limited to this. Rather, it can also be used for other material webs that exhibit similar winding behavior, for example metal or plastic films or cardboard webs.

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In one of the last manufacturing steps, a paper web, after it has been cut to the correct width if necessary, must be wound up into a winding roll so that it can be transported and handled. When winding the paper web into a roll, one of the goals is to achieve a predetermined winding hardness, i.e. the winding hardness should decrease from the inside to the outside or at least remain the same. You also want to prevent the roll from bending during winding. For this reason, the roller is used to support the winding roll against gravity. In many cases, however, the roller is not positioned directly below the winding roll in the direction of gravity, but offset to the side.

Such an arrangement can be found, for example, in a double-support roller winder, in which the winding roll lies in a winding bed formed by two support rollers. The two support rollers support the winding roll from below on the side. Another design is a winder in which the individual winding rolls lie alternately on both sides of a vertical plane in the upper quadrant of a support roller.

When winding, it is often necessary to know the diameter of the winding roll. This information is needed, for example, to be able to control the winding hardness. In many cases it is necessary to relieve the weight of the winding roll from a predetermined diameter of, for example, 800 mm. The information is also needed to be able to determine when enough paper has been wound onto the winding roll.

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Two methods are currently used to measure diameters. Firstly, the core speed, i.e. the speed of the winding roll, is compared to the speed of a roller over which the paper web runs, for example the roller that forms the support surface. Basically, the diameter of a roll is calculated from the circumference. Two pulse generators are required to measure the circumference. One is used to record the length of the paper, the other to determine the number of revolutions. In many cases, an average is taken over a certain number of revolutions, so that the diameter is calculated from the length of x layers divided by (π·x). For a quick display, for example, four layers are used. To calculate the density with a higher accuracy of, for example, 0.01 mm, 100 layers are used. The disadvantage of this procedure is that recording the number of revolutions of the winding roll is critical, for example if the core of the winding roll slips. There is also the risk of an initiator being destroyed, i.e. if the paper breaks off or the sleeve kicks out.

Another way of measuring the diameter is to determine the height of a load roller or winding head. From this height, the diameter can then be calculated using a relatively complicated polynomial function. However, this polynomial must be adapted to the respective geometry for each new type of paper. Calculation errors can arise from the geometric deviation.

The invention is based on the task of making the determination of the diameter simple -

it ti · t *· ·*

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This object is achieved in a roll winding device of the type mentioned at the outset in that the determination device has a length measuring device which determines a distance between the rotation axis of the winding roll and the rotation axis of the roller.

This distance increases proportionally with the roll diameter. It can be determined continuously with a high degree of accuracy and therefore provides continuous information about the diameter of the winding roll. A conversion is only necessary in the sense that the diameter of the roll must be taken into account. However, this is then a simple subtraction of a constant value, which can be carried out without any problem using modern computing or evaluation equipment. The distance between the rotation axis of the roll and the rotation axis of the winding roll is a distance between two points or parallel lines, so that one can be sure that these points can lie on a straight line. Inaccuracies due to conversions or similar can practically not be taken into account.

Preferably, the roller is arranged in a stationary manner. This facilitates the construction of the length measuring device. The length measuring device only has to detect a moving point and measure the distance between this moving point and the fixed point specified by the stationary roller.

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The roller preferably has a hard surface. Since the diameter must be determined very precisely, an elastic or flexible surface could result in inaccuracies, which depend on the weight of the winding roll, among other things. If, on the other hand, a hard roller is used, these inaccuracies cannot occur or only occur to a much lesser extent. The term "hard" is to be understood relatively here. The roller must be hard enough that the weight of the winding roll does not deform it to an extent that would change the measurement accuracy in an unacceptable way. If one assumes that a winding roll made of paper can still be deformed in an acceptable way, then the hardness of the support roller can still be selected so that it corresponds to the hardness of a paper roll.

It is particularly preferred if the roller is a support roller of a double support roller winder. With a double support roller winder, the problem of determining the diameter is particularly serious. The length measuring device makes determining the diameter much easier.

It is particularly preferred that the roller is the second roller of the double-roller winder in the direction of web travel. In many cases, this roller is not provided with an elastic surface layer.

Preferably, the detection device has a position sensor which is coupled to a winding head. The winding head is always connected to the winding core, i.e. to the center of the winding roll, in a predetermined relationship. From this, the position

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position of the rotation axis of the winding roll can be determined relatively easily. If you now move a position sensor together with the winding head, you can determine the length of the distance between the two rotation axes continuously or at short, discrete intervals with relatively little effort. The position sensor can be active or passive.

It is advantageous if the length measuring device is arranged on the outside of a frame, on the inside of which the roller and, if applicable, the winding head are arranged. This means that the length measuring device does not interfere with the actual winding process. The roller and the winding roll can move freely, as before. 15

The advantage here is that the winding head has a pin that extends outwards. This pin then continuously provides information about the position of the rotation axis of the winding roll. If necessary, the diameter of this pin must also be taken into account when determining the distance between the rotation axes of the roller and the winding roll.

The length measuring device is advantageously designed as a displacement sensor. Absolute displacement sensors such as angle encoders with a cable pull or cylindrical linear displacement sensors are suitable for this. The accuracy of such systems is around 0.1 mm. Of course, non-contact sensors are also conceivable, for example those that work with infrared or laser light or ultrasound.

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The invention is described in more detail below using a preferred embodiment in conjunction with the drawing.

Fig. 1 is a schematic front view and

Fig. 2 is a schematic side view of a winding device.

Fig. 1 shows a roll winding device 1 which is designed as a double support roller winder. The winding device 1 accordingly has two support rollers 2, 3 which together form a winding bed 4 in which a winding roll 5 rests, onto which an incoming material web 6, for example a paper web, is wound.

During winding, the winding roll 5 is driven in some way, for example on the circumference by a driven support roller 2, 3. However, it is also possible for the winding roll 5 to be driven via winding heads 7 (Fig. 2) which are arranged in a stand 8.

For controlling the winding process, it is advantageous to have constant knowledge of the diameter D of the winding roll 5. For example, you then know when the winding roll 5 is large enough to be able to end the winding process. In addition, you can also estimate the weight of the winding roll based on the diameter 0 and initiate loading or unloading measures accordingly, which can, for example, influence the

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course of the winding hardness or help prevent damage to the material web itself.

The determination of the diameter D is not possible by simply determining the height of the rotation axis 9 of the winding roll 5 in the stand 8, because the winding roll 5 migrates out of the winding bed 4 as its diameter increases. In order to be able to determine the diameter D from the height, a relatively complicated evaluation of a polynomial function is required, which in turn is subject to errors.

For this reason, a determination device 10 is used in the winding device 1, which determines a distance L between the winding axis 9 of the winding roll 5 and the rotation axis of the support roller 3. The diameter D of the winding roll 5 then results from the relationship

D = 2| Z-

where D _TW is the diameter of the support roller 3.

The length L increases linearly with increasing diameter D. The length L can therefore be measured using an absolute displacement sensor, which can be designed, for example, as an angle encoder with a cable pull or as a cylindrical linear displacement sensor. The accuracy of such systems is 0.1 mm/, which is sufficient to be able to control the winding process with sufficient accuracy.

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The support roller 3, whose axis is used as a difference point for determining the diameter D, is stationary. The determination device 10 therefore only has to take into account the change in one axis during winding. This support roller 3 is preferably not rubberized, i.e. it has a hard surface so that any flattening on the surface of the support roller 3 cannot negatively influence the measurement result. The hardness of the surface lies between the hardness of a steel or cast roller and the hardness of a paper roll.

The detection device 10 is arranged on the outside of the stand 8, for example on the guide side of the winding device 1. To do this, the winding head 7 on this side of the stand 8 can simply be provided with an extended pin and the support roller 3 can also be provided with an extended pin. In this case, the detection device 10 can simply measure the distance between the two pins. Since the diameter of the pins does not change during winding, these diameters can also be included in the calculation of the diameter of the winding roll 5.

The invention is not only applicable to a double support roller winder, as shown in the drawing, but basically to all roll winding devices in which the height of the rotation axis 0 9 of the winding roller 5 has no linear relationship with the diameter D of the winding roller 5. Accordingly, the detection device 10 can also be used, for example, in a support roller winder in which

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where the winding roll only rests on one support roller and is otherwise held on swivel arms.

What is essential here is that the determination device 10 is able to determine a linear distance between a fixed point and the axis of the winding roll 5, whereby a pivoting movement of the determination device 10 may be necessary if necessary.

Claims (9)

1. Roll winding device with at least one roller which forms a support surface for a winding roll, and with a determining device for determining a roll diameter of the winding roll, characterized in that the determining device ( 10 ) has a length measuring device which determines a distance (L) between the rotation axis ( 9 ) of the winding roll ( 5 ) and the rotation axis ( 11 ) of the roller ( 3 ). 2. Roll winding device according to claim 1, characterized in that the roller ( 3 ) is arranged in a fixed position. 3. Roll winding device according to claim 1 or 2, characterized in that the roller ( 3 ) has a hard surface. 4. Roll winding device according to one of claims 1 to 3, characterized in that the roller ( 3 ) is a support roller of a double support roller winder. 5. Roll winding device according to claim 4, characterized in that the roller ( 3 ) is the second roller of the double support roller winder in the web running direction. 6. Roll winding device according to one of claims 1 to 5, characterized in that the detection device ( 10 ) has a position sensor which is coupled to a winding head ( 7 ). 7. Roll winding device according to one of claims 1 to 6, characterized in that the length measuring device ( 10 ) is arranged on the outside of a frame ( 8 ), on the inside of which the roller ( 3 ) and optionally the winding head ( 7 ) are arranged. 8. Roll winding device according to claim 7, characterized in that the winding head ( 7 ) has an outwardly extended pin. 9. Roll winding device according to one of claims 1 to 8, characterized in that the length measuring device ( 10 ) is designed as a displacement sensor.