EP3461769B1 - Method and a coiling device of a paper machine - Google Patents

Description

The invention relates to a method and a system, in particular a winding device of a paper machine. The invention further relates to a computer program product.

Winding devices are used to wind up a paper web in a paper machine. When winding or unwinding the paper roll, the diameter of the paper roll changes with every revolution. For a constant speed of the paper web, a continuous determination of the speed of rotation and the diameter of the paper roll are therefore advantageous.

So far, the diameter of the paper roll has been determined using a laser-based sensor. The optical components of the laser-based sensor often have to be cleaned disadvantageously. If the laser-assisted sensor is not cleaned in time, the laser-assisted sensor can fail. A sensor failure can result in a paper machine failure.

U.S. 4,951,567 A. discloses a security system for a printing press with at least one machine drive, a braking device and an electronic control therefor. The control electronics enable the drive arrangement to be braked electronically and has a monitoring circuit to which the setpoint and actual values of the rotational speed of the drive arrangement can be fed and which activates the braking device in the event of an impermissibly high deviation between a setpoint and an actual value.

US 2002/017212 A1 discloses a method for detecting errors in the transport of a web in a printing press, in which the web speed by a non-contact measurement is determined according to the Doppler principle. A first local path speed at a first measuring position and at least one second local path speed at a second measuring position are determined by means of microwaves. An actual value is determined from the first local web speed and at least the second local web speed. Furthermore, a deviation of the actual value from a predetermined target value is determined and compared with a predetermined threshold value.

It is an object of the invention to increase the operational safety of a paper machine, in particular a winding device.

The object is achieved by a method according to claim 1 and by a winding device according to claim 9.

Advantageous further developments and embodiments are the subject of the dependent claims.

It is an aspect of the invention to replace the laser-based sensor. The laser-based sensor can be replaced by another encoder to determine the speed of rotation. Alternatively or additionally, the speed of rotation can also be determined with the aid of a frequency converter. A value of the speed of the web is preferably determined from the respective rotational speed.

• mit einem zweiten Geber bestimmt wird und/oder
• von dem Frequenzumrichter bereitgestellt wird,

und wobei anhand der ersten Drehgeschwindigkeit eine erste Geschwindigkeit der Warenbahn ermittelt wird, wobei anhand der zweiten Drehgeschwindigkeit eine zweite Geschwindigkeit der Warenbahn ermittelt wird und wobei bei einer unvorhergesehenen Abweichung der ersten Geschwindigkeit der Warenbahn von der zweiten Geschwindigkeit der Warenbahn die Anlage in einen sicheren Zustand überführt wird.In the method for operating a system, in particular a paper machine, preferably a winding device of a paper machine, the system has a roller with a variable diameter and a motor, the motor serving to drive the roller, the motor being driven by a frequency converter with a motor current is supplied, wherein a first rotational speed of the roller or the motor and a second rotational speed of the roller or the motor is determined, wherein the first rotational speed is determined with a first encoder and wherein the second rotational speed

• is determined with a second encoder and / or
• is provided by the frequency converter,

and wherein a first speed of the material web is determined on the basis of the first rotational speed, a second speed of the material web is determined on the basis of the second rotational speed and, in the event of an unforeseen deviation of the first speed of the material web from the second speed of the material web, the system is brought into a safe state becomes.

The first speed of the web is preferably compared with the second speed of the web. Alternatively or additionally, the first rotational speed is preferably compared with the second rotational speed.

If the speeds differ from one another, a warning signal can be provided. The respective speed of the web can be compared with a predetermined speed for the web. The specified speed is an example of a maximum speed. In particular, the roller has a variable diameter. The diameter of the roll can change over time. The diameter of the roll can change due to the web of material wound or unwound on the roll. The diameter of the roll is a measure of the number of wound or unwound layers of the web.

The motor is preferably used to drive the roller. The motor preferably has the first transmitter. Optionally, the motor also has the second encoder.

In the safe state of the system, the respective motor of the system can be switched off. Alternatively, the web can be moved at the lowest possible speed.

The second encoder is preferably also assigned to the motor. The second encoder can also be assigned directly to the roller with the variable diameter. The rotation speed of the roller is determined directly by assigning the second encoder to the roller.

In addition, the second transmitter can also be assigned to another role, in particular another role, preferably with a constant diameter. The second encoder can thus also be assigned to a further motor, the further motor serving to drive the further roller.

On the basis of a calculation of the diameter of the roll with the variable diameter based on the number of rolled-up layers of paper, the speed of the material web can easily be determined using the speed of the roll.

The second encoder can also be assigned to a roller with a constant diameter. By determining the speed of rotation of the roll with the constant diameter, the speed of the web can easily be determined. In this case, the speed of the web is proportional to the product of the diameter and the respective speed of rotation of the roll.

Additionally or alternatively, the second rotational speed can also be provided with the aid of the frequency converter. The second rotational speed is preferably determined using the frequency converter by analyzing the motor current provided.

Since the web generally has a high modulus of elasticity and / or only a minimal slip between the web and the respective roll, the tangential speed of the respective roll corresponds to the speed of the web.

By using a second encoder and / or by determining the rotational speed with the aid of the frequency converter, the speed of the material web can be determined twice and thus particularly reliably.

By determining the speed of the web in duplicate, the failure of a sensor or an encoder can be effectively compensated. This increases operational safety.

The invention is particularly advantageously used to obtain a SIL-2 certification for a system, in particular for a paper machine.

In an advantageous embodiment of the invention, the first speed of the web is determined by the speed of rotation of a further roll.

The further roller preferably has a constant diameter. On the basis of the constant diameter, the speed of the material web can be inferred directly from the rotational speed of the further roll. The speed of rotation of the further roller is determined with at least one encoder. The rotational speed of the further roller is advantageously determined using a first encoder and a second encoder.

The first encoder and the second encoder are advantageously arranged on the motor that drives the roller with the constant diameter.

By directly determining the speed of the web, it is not necessary to consider the thickness of the web.

In a further advantageous embodiment of the invention, the first and / or second speed is based on the first rotational speed and / or the second rotational speed the web is determined via the respective tangential speed of the roll.

To determine the speed of the web, the tangential speed of a roll can be determined by the respective speed of rotation of the roll. The respective tangential speed is proportional to the speed of rotation of the respective roller. In the case of a roll with a variable diameter, the diameter is preferably adjusted by simulating or calculating the diameter of the roll.

Assuming that there is essentially no slippage between the respective roll and the web, the respective tangential speed of the roll corresponds to the speed of the web.

The calculation can be simplified by calculating the speed of the web based on the respective tangential speed. Parameters such as a modulus of elasticity of the web can also be advantageously determined.

In a further advantageous embodiment of the invention, the diameter of the roller is variable.

The diameter of the roll usually changes in the case of a roll in which the web is wound up or unwound. With a constant thickness, the change in the diameter of the web is proportional to the number of layers of the web that are (still) wound on the roll.

By considering a changing diameter of the roll, the invention can be applied to a winding device.

A winding device with a SIL-2 certification can also be provided.

In a further advantageous embodiment of the invention, the diameter of a further roller is constant and the second transmitter is assigned to the further roller.

The second roller is advantageously used to deflect the web. The further roll therefore has a constant tangential speed at a constant web speed. The speed of the web is proportional to the speed of rotation of the further roll.

If the further role is assigned to a further motor, the second encoder can be assigned to the further motor.

By assigning the second encoder to a roll with a constant diameter, the respective speed of the material web can be determined particularly easily on the basis of the respective rotational speed.

In a further advantageous embodiment of the invention, the first and second rotational speeds are compared in terms of magnitude and direction, and a warning signal is output at different rotational speeds.

The comparison is preferably carried out in a control device and / or with the aid of a computer program. A comparison of the respective rotational speeds and / or a comparison of the respectively determined speed of the material web can take place. The respectively determined tangential speeds of the respective roll can also be compared with one another. By comparing the respective rotational speeds, the system can be brought into the safe state if the (rotational) speeds deviate.

A comparison of the (rotational or tangential) speeds can advantageously be used to determine a web break or other disruption.

In a further advantageous embodiment of the invention, the first rotational speed and / or the second rotational speed are each provided to a first control device and an optional second control device.

The control device is preferably used to determine the respective speed of the material web on the basis of the rotational speed provided in each case. If the first speed deviates from the second speed of the material web, the first control device and / or the optional second control device can provide the warning signal. If two control devices are present, the control devices are advantageously designed redundantly.

The speed of the material web is preferably determined using the first rotational speed in the first control device and the speed of the material web is determined using the second rotational speed using a second control device.

The respective determination of the speed of the material web is preferably carried out independently of one another from the respective rotational speed. The first speed can also be determined independently, in particular redundantly, in the respective control device from the determination of the second speed.

Preferably, the speed of the material web is determined based on the first rotational speed in a first time period and the speed of the material web is determined based on the second rotational speed in a second time period. The time periods can be disjoint and / or alternate.

If the first control device fails, the second control device preferably takes over the tasks of the first Control device. With a redundant design of the control devices, taking over the tasks is simplified.

The multiple determination of the speed of rotation also enables the tangential speed of the respective roll to be determined multiple times and / or the speed of the material web to be determined multiple times.

The operational safety of the system can be increased by the double execution of the control device.

In a further advantageous embodiment of the invention, the second encoder determines the rotational speed of the respective roller directly.

Preferably, the first and the second transmitter are each positioned on a roller in such a way that the respective transmitter directly determines the rotational speed of the respective roller. The direct or immediate determination of the respective rotational speed is preferably carried out by arranging the respective encoder on the respective roller.

By directly determining the respective rotational speed, the speed of the material web can take place independently of any inaccuracies that may occur during the transmission of the respective rotational speed.

The first and the second transmitter are further preferably positioned on the roller with the variable diameter.

The direct determination is made by positioning the respective encoder on the respective role. Due to the direct positioning of the second encoder on the roller, inaccuracies in the transmission of the rotary movement between the motor and roller can be excluded.

In a further advantageous embodiment of the invention, based on the first speed of the web and / or the second speed of the web, the respective rotational speed is provided, the respective control device controlling or regulating the respective rotational speed of the motor such that the respective speed of the web does not exceed a maximum speed.

The (re) determination of the respective rotational speed from the determined speed of the material web is advantageously carried out analogously to a control loop. The respective rotational speed is preferably provided to the frequency converter. The frequency converter controls or regulates the speed of rotation of the motor. A maximum rotational speed can result from the specification of a maximum speed of the material web.

By specifying the respective rotational speed of the respective roll or the respective motor, it can be ensured that a maximum speed of the material web is not exceeded.

In particular, a SIL2 certification of the system can be achieved.

In a further advantageous embodiment of the invention, the first rotational speed and / or the second rotational speed ensure that the speed of the material web does not exceed a predetermined value.

The set value for the speed of the web is preferably a maximum value, e.g. 20 m / s. The maximum value is preferably predetermined. The maximum value is preferably different for different operating modes of the system.

By ensuring that the speed of the web does not exceed the set value, a safe one Operating mode, for example after starting the system, can be designed particularly safely.

In a further advantageous embodiment of the invention, a plausibility check is carried out to determine whether the first speed, which was determined from the first rotational speed, is equal to the second speed, which was determined from the second rotational speed.

The plausibility check is preferably carried out in the control device. In the case of two control devices, the plausibility check is advantageously carried out redundantly in the respective control device. The plausibility checks are preferably carried out independently of one another.

If the first and second speeds of the material web in direction and height essentially match, the plausibility check is fulfilled.

The plausibility check can advantageously be used to check whether the sensors and / or the control device are functioning properly.

• der Rolle ein zweiter Geber zugeordnet ist und der zweite Geber zur Bereitstellung einer zweiten Drehgeschwindigkeit an eine Steuereinrichtung ausgebildet ist, und/oder
• der Frequenzumrichter zur Bereitstellung einer zweiten Drehgeschwindigkeit an die Steuereinrichtung vorgesehen ist,

wobei anhand der ersten Drehgeschwindigkeit eine erste Geschwindigkeit der Warenbahn ermittelt wird und anhand der zweiten Drehgeschwindigkeit eine zweite Geschwindigkeit der Warenbahn ermittelt wird,
wobei die Steuereinrichtung zur Ausgabe eines Warnsignals ausgebildet ist, falls die erste und die zweite Drehgeschwindigkeit oder die erste Geschwindigkeit der Warenbahn und die zweite Geschwindigkeit der Warenbahn unterschiedlich sind.The system, in particular at least part of a paper machine, preferably a winding device, has a roller, the roller being designed, in particular, for receiving or dispensing a material web, the roller being connected to a motor, the motor for driving the roller with a rotational speed is formed, the motor being connected to a frequency converter, the motor being associated with a first encoder and the first encoder being provided for providing a first rotational speed, wherein

• a second transmitter is assigned to the roller and the second transmitter is designed to provide a second rotational speed to a control device, and / or
• the frequency converter is provided for providing a second rotational speed to the control device,

wherein a first speed of the web is determined on the basis of the first rotational speed and a second speed of the web is determined on the basis of the second rotational speed,
wherein the control device is designed to output a warning signal if the first and the second rotational speed or the first speed of the web and the second speed of the web are different.

Both the first and the second transmitter are preferably positioned on the respective motor.

Alternatively or additionally, the second transmitter can be positioned on the roller itself. The second encoder can then directly determine the speed of rotation of the roller. The second encoder can also be assigned to the shaft of the respective role.

The second encoder can also be assigned to a further role, in particular with a constant diameter. The other roller can also be driven by another motor. The second encoder can be assigned to the other motor.

A particularly safe mode of operation results if, in the event of failure of one of the encoders, the respective rotational speed is determined with the help of the other encoder. The system can then continue to be operated in a safe mode until the error has been rectified.

If the respective speed of the material web does not change, in the event of a failure of one of the transmitters, there is advantageously no provision of a warning signal or transfer of the system to the safe operating state.

Due to the design of the system described here, the system can be operated in a particularly simple manner.

When the frequency converter provides the second rotational speed, the provision can take place with the aid of a "fail-safe" rotational speed determination. For this purpose, "fail-safe" drive components (so-called F-CPU's) are preferably provided, such as a "fail-safe" frequency converter. Drive components from Siemens AG are particularly suitable.

In the "fail-safe" rotation speed determination, the rotation speed provided is preferably checked with a further rotation speed, which was calculated as an example.

In a further advantageous embodiment of the invention, the system has a first and a second control device, the respective control device being designed in each case for specifying the rotational speed of the respective motor.

The first and the second control device are preferably designed redundantly.

The operational safety can be increased further by the multiple configuration of the respective control device.

In a further advantageous embodiment of the invention, the frequency converter comprises a rotation speed determination, the rotation speed determination being designed to provide the second rotation speed and / or the second speed of the material web.

Modern frequency converters generally have a rotational speed determination. This is usually used to provide the speed of rotation of the motor connected to the frequency converter.

By providing the speed of the material web by the frequency converter, the second encoder can advantageously be saved and / or the control device can be relieved.

In a further advantageous embodiment of the invention, the system is a paper machine, in particular a winding device.

The invention can be used for a winding device and / or an unwinding device of a web. The web is preferably a cellulose-containing web, such as a paper web. Another possible application of the invention is a tubular bag machine or a wire winding machine.

The first and second sensors are preferably assigned to the motor that rotates the variable diameter roller. In particular, both encoders are positioned on the same motor. In this way, an offset due to deviations or slippage between the two rotational speeds can be avoided.

If one of the sensors fails, the respective rotational speed can be provided by the frequency converter, in particular by determining the rotational speed.

A failure of the encoder does not necessarily lead to the system being brought into a safe state.

With the help of the frequency converter, the function of the respective encoder can be checked by comparing the respective rotational speed of the encoder with the rotational speed that is provided by the frequency converter.

Such a comparison can take place at the beginning of the operating time of the system and / or at recurring times during the operation of the system.

• der ersten Geschwindigkeit der Warenbahn,
• der zweiten Geschwindigkeit der Warenbahn,
• und/oder eines Warnsignals,

ausgebildet ist.The computer program product for executing the method on a computing unit, the computing unit being assigned to at least one control device and the computer program product for providing the method described here

• the first speed of the web,
• the second speed of the web,
• and / or a warning signal,

is trained.

A plausibility check of the speeds and / or the rotational speeds serves to provide the warning signal, the warning signal being provided if the first (rotational) speed deviates from the second (rotational) speed.

The computing unit can be designed as a microcontroller. The computing unit can also be integrated in the respective control device.

FIG 1

eine Wickeleinrichtung,

FIG 2

einen Ausschnitt einer Steuereinrichtung,

FIG 3

zwei Steuereinrichtungen,

FIG 4

einen Ausschnitt aus einer Papiermaschine sowie

FIG 5

eine weitere Wickeleinrichtung.

The invention is described and explained in more detail below with reference to figures. The figures show embodiments of the invention, and the features shown can again be combined to new embodiments of the invention. Show it

FIG 1

a winding device,

FIG 2

a section of a control device,

FIG 3

two control devices,

FIG 4

a section of a paper machine as well

FIG 5

another winding device.

FIG 1 shows a winding device. The winding device serves to wind up a web 1. The web 1 is an example of a paper web that is produced in a paper machine. The web 1 moves at a speed V1, V2 in the direction of a roll 3, the roll 3 having a variable (increasing in time) diameter d due to the wound web 1. The role 3 rotates on a shaft 11 and is positioned by the shaft 11. Part of the web 1 is already rolled up on the roll 3. This part is referred to as the wound web 1a. The wound web 1a defines the diameter d of the roll 3.

The speed V of the paper web is determined with a first sensor 9a and a second sensor 9b.

The first encoder 9a is used to determine the first rotational speed D1 of the roller with a variable diameter d. The second encoder 9b is used to determine the second rotational speed D2 of the roller 3 with a variable diameter d. The first transmitter 9a and the second transmitter 9b each transmit a signal to a control device 13. The control device 13 is used in particular to determine the speed V of the web 1. The speed V of the web 1 is determined, for example, by calculating the tangential speed Vt of the roll 3 with variable diameter d.

The first encoder 9a is positioned in the motor 5. The motor 5 is supplied with a motor current by a frequency converter 7. The frequency converter 7 has a rotational speed determination 7F. The rotational speed determination 7F serves to determine the second rotational speed D2. The second rotational speed D2, which was determined with the aid of the rotational speed determination 7F of the converter, is also made available to the control device 13. The rotational speed determination 7F is preferably designed as a "fail-safe" rotational speed determination 7F.

The first speed V1 of the material web 1 is preferably provided from the first rotational speed D1 with the aid of the control device 13. The second speed V2 of the web 1 is provided from the second rotational speed D2. The second speed V2 of the web 1 is alternatively or additionally provided by the frequency converter 7.

The control device 13 is preferably used to ensure a maximum speed of the web 1. The control device 13 is preferably used to control the motor 5 by providing control signals to the frequency converter 7. If the first speed V1 deviates from the second speed V2, the control device provides a warning signal WS. The warning signal WS is used to transfer the system to a safe state.

FIG 2 shows the detail of a control device 13. The control device 13 or a module of the control device each has an input for the first rotational speed D1 and for the second rotational speed D2. In a comparison module 15, the first rotational speed D1 is compared with the second rotational speed D2. If the first rotational speed D1 and the second rotational speed D2 deviate, a warning signal is output. The warning signal is used in particular to bring the system into a safe state.

The respective rotational speed D1, D2 is also provided to a calculation unit F1, F2. The respective calculation unit F1, F2 is used to calculate the respective speed V of the web 1. In a redundant design of the control device 13, the first calculation unit F1 can be assigned to the first control device 13a and the second calculation unit F2 to the second control device 13b.

Alternatively, the speed V of the web 1 or the respective tangential speed Vt can first be determined from the respective rotational speed D1, D2 and these can be compared with one another.

FIG 3 shows two control devices 13a, 13b. The control devices 13a, 13b are preferably designed redundantly. The redundant design of the control devices 13a, 13b can ensure an increase in operational reliability, insofar as one of the control devices 13a, 13b can control the system if one of the control devices 13a, 13b fails.

It is shown that the first rotational speed D1 and the second rotational speed D2 are respectively provided to the first control device 13a and that of the second control device 13b.

The first control device 13a and / or the second control device 13b calculate the tangential speed Vt of the respective roller 3, 4 from at least one of the rotational speeds D1, D2. The respective control devices 13a, 13b preferably also calculate the first and / or second speed V1, V2 der Material web 1. The respective speed V1, V2 and / or the tangential speed Vt is provided to the frequency converter 7 in each case.

The frequency converter 7 controls the rotational speed D1, D2 of the motor 5 and the roller 3 on the basis of the speed V and / or the tangential speed Vt of the roller 3.

FIG 4 shows a section of a paper machine. Here, the web 1, in particular a cellulose-containing web such as paper, is passed over a further roll 4 and the roll 3 is rolled up with a variable diameter d. The diameter d of the roll 3 changes due to the rolling / unrolling of the web 1 onto the roll 3. Another roll 4 has a constant diameter d. Here, the first encoder 9a is assigned to the roller 3 with the variable diameter d. The second encoder 9b is assigned to the further roller 4 with the constant diameter d. Roll 3 and further roll 4 are preferably each assigned to a motor. In this case, the respective transmitter 9a, 9b be assigned to the respective motor 5, which moves the respective roller 3, 4 (rotating).

FIG 5 shows another winding device. Shown is a web 1 which is moved along a further roll 4 at a speed v1, v2. The material web 1 is rolled up on a roll 3 with a variable diameter d. Both the roller 3 with a variable diameter d and the further roller 4 with a constant diameter are each driven by a motor 5. The respective motor 5 has a first sensor 9a and a second sensor 9b. Depending on the configuration, some of the sensors 9a, 9b can also be arranged directly on one of the rollers 3, 4. The respective

The respective roller has a tangential speed Vt. If the web of material breaks, the respective tangential speeds Vt of the rollers 3, 4 would differ. With a normally provided function of the winding device or a normally provided function of the paper machine, the tangential speeds Vt are essentially the same. The respectively determined rotational speeds D1, D2 are made available to the control device 13. The control device 13 can also be designed redundantly with a further control device (not shown).

The operational safety can be increased by double monitoring of the respective rotational speeds of the rollers 3, 4.

In summary, the invention relates to a method and an installation. The method is used for a particularly safe operation of the system. According to the method, a first rotational speed D1 and a second rotational speed D2 are determined. With the aid of the first rotational speed D1 and / or the second rotational speed D2, a speed V1, V2 of a material web 1 is determined in each case. The first rotational speed D1 is determined using a first encoder 9a determined. The second rotational speed D2 is determined with the aid of a second encoder 9b and / or a rotational speed determination 7F, in particular as part of a frequency converter 7. Due to the multiple determination of the rotational speed D1, D2 or the speed V1, V2 of the web 1, the system has a high level of operational reliability. Fields of application of the invention are in particular a paper machine, a printing machine, a tubular bag machine or a winding device.

Claims (11)

1. Method for operating a coiling installation of a paper machine, wherein the coiling installation has a roll (3) having a variable diameter (d) and a motor (5), wherein the motor (5) serves for driving the roll (3, 4), wherein the motor (5) is supplied with a motor current by a frequency inverter (7), wherein a first rotating speed (D1) of the roll (3, 4) or of the motor (5) and a second rotating speed (D2) of the roll (3, 4) or of the motor (5) are determined, wherein the first rotating speed (D1) is determined by a first encoder (9a) and wherein the second rotating speed (D2) is provided by the frequency inverter (7), and wherein a first speed (v1) of the material web is determined by means of the first rotating speed (D1), wherein a second speed (v2) of the material web (1) is determined by means of the second rotating speed (D2), and wherein in the event of an unforeseen deviation of the first rotating speed (V1) of the material web (1) from the second speed (V2) of the material web (1) the coiling installation is converted to a safe state.
2. Method according to Claim 1, wherein the speed (v1, v2) of the material web (1) is determined by the rotating speed (D1, D2) of a further roll (4).
3. Method according to Claim 1 or 2, wherein the first speed (V1) of the material web (1) and the second speed (V2) of the material web (1) by means of the first rotating speed (D1) and/or of the second rotating speed (D2) is ascertained with the aid of a tangential speed (Vt) of the roll (3, 4).
4. Method according to one of the preceding claims, wherein the diameter (d) of the roll (3) is variable.
5. Method according to one of the preceding claims, wherein the first rotating speed (D1) and the second rotating speed (D2) are compared in terms of value and direction, and a warning signal is emitted in the event of dissimilar rotating speeds (D1, D2).
6. Method according to one of the preceding claims, wherein the first rotating speed (D1) and/or the second rotating speed (D2) are in each case provided to a first control installation (13a) and a second control installation (13b), wherein the respective control installation (13a, 13b) provides the respective rotating speed (D1, D2) for the motor (5).
7. Method according to one of the preceding claims, wherein the respective rotating speed (D1, D2) is provided by means of the first speed (V1) and/or the second speed (V2) such that the respective speed (V1, V2) of the material web (1) does not exceed a maximum speed.
8. Method according to one of the preceding claims, wherein a plausibility test as to whether the identical speed (V1, V2) of the material web (1) is in each case present by means of the first rotating speed (D1) and the second rotating speed (D2) .
9. Coiling installation of a paper machine, having a roll (3), wherein the roll is in particular configured for receiving or dispensing a material web (1), wherein the roll (3, 4) is connected to a motor (5), wherein the motor (5) is configured for driving the roll (3) at a rotating speed (D1, D2), wherein the motor (5) is connected to a frequency inverter (7), wherein the motor (5) is assigned a first encoder (9a) and the first encoder (9a) is provided for providing a first rotating speed (D1), wherein the frequency inverter (7) is provided for providing a second rotating speed (D2) to the control installation (13, 13a, 13b), wherein a first speed (V1) of the material web (1) is ascertained by means of the first rotating speed (D1) and a second speed (V2) of the material web (1) is ascertained by means of the second rotating speed (D2), wherein the control installation (13, 13a, 13b) is configured for emitting a warning signal (WS) should the first rotating speed (D1) and the second rotating speed (D2), or the first speed (V1) of the material web and the second speed (V2) of the material web (1) be dissimilar.
10. Coiling installation according to Claim 9, having a first control installation (13a) and a second control installation (13b), wherein the control installations (13a, 13b) are in each case configured for predefining the respective rotating speed (D1, D2) of the respective motor (5).
11. Coiling installation according to one of Claims 9 or 10, wherein the frequency inverter (7) has a rotating speed ascertainment (7F), and the rotating speed ascertainment (7F) is provided for providing the second rotating speed (D2) and/or the second speed (V2) of the material web (1).

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