EP0502408A1 - Method of and device for controlling webs - Google Patents

Abstract

In the control of a web (2) in a web-processing machine, especially in a pressure machine, using at least one sensor (10) arranged in the area of the path of the web (2), which sensor has a transmitter (8) for a control beam (12) pointing towards the web (2) and a receiver (9) for a beam (13) reflected back from the web (2) and is connected to a signal processing device (11), by means of which the space between transmission of the control beam (12) and reception of the reflected beam (13) can be measured and a control pulse can be generated if a preset belt width is exceeded, a high degree of reliability and safety are achieved by making the signal processing device (11) a computer which has an input for a web speed signal and is programmed in such a way that a belt width (B) is set before the speed signal is received, this belt width (B) being preferably different from and greater than the belt width after the speed signal has been received. <IMAGE>

Description

According to a first concept of the invention, the invention relates to a method for monitoring a web in a machine processing a web, in particular in a printing machine, according to the preamble of claim 1, and according to a further concept of the invention relates to a device for carrying out this method according to the preamble of claim 6.

So far, a fixed bandwidth has been used, which is accordingly effective for all speeds of the web. As long as the train is within this range, nothing happens. As soon as there are no more lanes within the specified bandwidth a control pulse is emitted, which is generally used to switch off the machine and / or to catch and / or to separate the web. The disadvantage here is that the web does not run smoothly at any speed, but tends to flutter in many cases. In the case of the paper web to be printed in a printing press, this is generally the case when the web is drawn in and when the machine is started up. There is therefore the risk that the web will already fall outside the intended range due to its fluttering movements, which must not be too great to avoid dead times. The consequence of this is a false pulse, ie the display of a web break without it actually being present.

An increase in the bandwidth would avoid false signals when the web was pulled in or when the machine was started, but would cause a comparatively high response inertia in normal operation at full speed, which is undesirable. So far, compromises have been made, which, however, do not guarantee sufficient reliability when entering the web or starting the machine and do not guarantee adequate safety during normal operation.

Proceeding from this, it is therefore the object of the present invention to improve a method and a device of the generic type with simple and inexpensive means so that an optimal monitoring result is achieved in every operating state.

The procedural solution to this problem is specified in the characterizing part of claim 1. The device-like solution to this problem is specified in the characterizing part of claim 6.

The advantages that can be achieved with the measures according to the invention are primarily to be seen in the avoidance of the disadvantages described at the outset. The measures according to the invention thus provide a simple possibility of avoiding false pulses by using a larger bandwidth within operating phases in which larger flutter movements of the web are to be expected. Nevertheless, low idleness and, accordingly, a high level of safety can be guaranteed in operating phases in which the web is expected to run smoothly.

The bandwidth, when a control pulse is emitted, can advantageously be changed stepwise, expediently in the form of a step. This results in a particularly simple design.

Another useful measure can be that the computer forming a signal processing device is programmed so that at least the distance between the web and the sensor when the speed signal arrives is measured and this distance can be set as the center of the preferably smaller bandwidth that can be set after the speed signal arrives. These measures advantageously ensure self-adjustment of the sensor. The accuracy of assembly is therefore no longer so important as until now. Another advantage is that, as a result of the self-adjustment mentioned, even with arrangements with several possible paper paths, one sensor is sufficient for all paper paths, since the sensor adjusts itself to the path chosen in each case.

Further advantageous refinements and expedient further training of the higher-level measures are specified in the remaining subclaims.

Figur 1

eine schematische Ansicht einer Rollenrotationsdruckmaschine mit erfindungsgemäßer Überwachungseinrichtung zur Betätigung einer Bahnfangvorrichtung,

Figur 2

ein Zeitdiagramm des Überwachungs- und Reflexionsstrahls und

Figur 3

ein Zeitdiagramm der zulässigen Bandbreite über der Maschinengeschwindigkeit.

An exemplary embodiment of the invention is explained in more detail below with reference to the drawing. Here show:

Figure 1

1 shows a schematic view of a web-fed rotary printing press with a monitoring device according to the invention for actuating a web catching device

Figure 2

a timing diagram of the monitoring and reflection beam and

Figure 3

a time diagram of the permitted bandwidth over the machine speed.

The web-fed rotary printing machine indicated in FIG. 1 by a printing unit 1 is used for printing on a paper web 2. As a rule, several printing units arranged one behind the other are provided, of which only the last one is shown in FIG. 1. Following the last printing unit, the paper web 2 passes through a dryer 3.

With arrangements of this type, there is a risk that the paper web 2 will wind up on a printing unit cylinder 4 in the event of a web break, which can lead to machine damage. For this reason, web catch devices 5 assigned to the printing units 1 are used, which can be activated by means of an assigned web break switch 6, as indicated in FIG. 1 by a signal line 7. FIG. 1 shows a web catching device 5 arranged in the outlet area of the last printing unit 1. The assigned web break switch 6 is located in the area of the dryer entrance.

The web break switch 6 contains a sensor 10 consisting of a transmitter 8 and a receiver 9, which is connected to a signal processing device 11 from which the signal line 7 extends. The transmitter 8, which is designed as a high-frequency generator, emits a monitoring beam 12 directed at the web 2, which is reflected by the web 2. The resulting reflection beam 13 is received by the receiver 9. The beams 12, 13 can be light beams or preferably ultrasound beams.

The time difference .DELTA.t indicated in FIG. 2 lies between the exit of the monitoring beam 12 indicated by a solid line from the transmitter 8 and the corresponding arrival of the reflection beam 13 indicated by dashed lines in FIG. 2 at the receiver 9. From this time difference and the propagation speed, in the case of ultrasound beams of the speed of sound, the distance of the web 2 from the sensor 10 indicated in FIG. 1 at d 1 can be determined.

wobei

c die Fortpflanzungsgeschwindigkeit, d der Abstand und Δt die Zeitdifferenz sind. In diesem Zusammenhang ist zu berücksichtigen, daß die gegenseitige Neigung der beiden Strahlen 12, 13 in der Praxis wesentlich kleiner als in der vorliegenden, schematischen Darstellung ist.The relevant formula is:

$$\frac{\text{Δt}}{\text{2nd}}\text{. c = d,}$$

in which

c is the rate of reproduction, d is the distance and Δt is the time difference. In this context, it should be taken into account that the mutual inclination of the two beams 12, 13 is in practice much smaller than in the present schematic illustration.

As long as the measured time difference .DELTA.t and thus the distance d determined therefrom lie within an approved range, the safety device 5 remains passivated. As soon as the amount of Δt or d is no longer in an approved range, i.e. no presence of web 2 is found within the permitted range, this is interpreted as a web break. In this case, a control pulse is generated by the signal processing device 11 connected to the sensor 10, by means of which the web guiding device 5 is activated and the machine drive of the printing press is switched off and braked.

The required arithmetic operation is carried out by the signal processing device 11. Accordingly, a programmable computer designed as a microprocessor is provided to form the signal processing device 11. This is programmed so that it switches from a certain speed of the web 2 from a larger area indicated in FIG. 1 at B for the permissible position of the web 2 and accordingly for the distance d to a smaller area indicated in FIG. 1 at b . The resulting from the areas B and b for the permissible position of the web 2 Bandwidths for the distance d between web 2 and sensor 10 are indicated in FIG. 3 at B 'and b'. As already mentioned, the time difference is measured, from which the distance is determined using the above formula. The same bandwidths therefore apply to the time difference.

The switch from the larger band width to the smaller band can, as can be seen in FIG. 3 with the step S, take place in a web-fed rotary printing press of the present type when the web 2 has reached approximately 10% of its intended final speed. The computer forming the signal processing device 11 is accordingly provided with an input 11a for a web speed signal. At this input there is a signal line 15 coming from a speed sensor 14. As soon as the machine and, accordingly, the web 2 reach the predetermined speed, the computer forming the signal processing device 11 receives a pulse via the signal line 15, which triggers the aforementioned change from B to b .

This ensures that, as indicated in Figure 3, below a predetermined web speed v₁, here in the form of 10% of the final speed, a large bandwidth B 'is effective for the distance d, within which the web 2 can flutter without this leads to an activation of the safety device 5. This large bandwidth B 'is larger than the expected deflections of the web 2 when the web 2 is drawn in or when the machine starts up. From the intended speed v 1, the smaller bandwidth b' is effective, within which the web 2 at higher web speeds can flutter. In this context, it can be assumed that in a web-fed rotary printing press of the type in question, web 2 runs more smoothly at high speeds than in the lower speed range. As a result of the reduced bandwidth b 'in the upper speed range, however, there is a short dead time between the occurrence of a web break and the response of the safety device 5.

The sensor 10 is installed in such a way that the theoretical transport plane of the web 2 lies approximately in the middle of the larger bandwidth B '. Due to assembly inaccuracies, however, deviations can occur, which, however, does not play a significant role in the area of the larger bandwidth B, as indicated in FIG. 3 by the asymmetrical position of the larger bandwidth B 'relative to the plane of the path indicated by a dash-dotted line. In the area of the smaller bandwidth b ', these inaccuracies are excluded. For this purpose, the computer forming the signal processing device 11 is programmed such that it takes the distance d 1 between the web 2 and the sensor 10, measured when the above-mentioned speed signal is received, as the center of the smaller bandwidth b ', so that, as can be seen from FIG. 3, this increases symmetrically the path level indicated by a dash-dotted line. Accordingly, self-adjustment takes place independently of the sensor assembly. The same applies in the event that there are several possibilities in the machine for the path of the web 2, as is often the case in folders, for example. Even in cases of this type, the sensor 10 adjusts itself to the path of the path 2 chosen in each case.

Claims (9)

Method for monitoring a web in a web processing machine, in particular in a printing press, in which a web is applied to a monitoring beam, the reflection of which is received and in which the distance between the transmission of the monitoring beam and the reception of the reflection beam is measured, and in the case of a a control pulse can be generated if the distance exceeds the predetermined bandwidth, characterized in that the bandwidth, when a control pulse is emitted, is dependent on the web speed. Method according to claim 1, characterized in that the bandwidth, when a control pulse is emitted, is reduced as the web speed increases. Method according to one of the preceding claims, characterized in that the bandwidth, above which a control pulse is emitted, is changed in steps, preferably in the form of a step. Method according to Claim 3, characterized in that the bandwidth, when a control pulse is emitted when it is exceeded, is reduced when a predetermined path speed, preferably 10% of the final speed, is exceeded. Method according to one of the preceding claims, characterized in that the distance (d) between the web (2) and the sensor (10) measured during the transition from the larger bandwidth (B) to the smaller bandwidth (b) is recorded and as an average for the smaller one Bandwidth (b) is used. Device for carrying out the method according to one of the preceding claims, with at least one sensor (10) arranged in the region of the path of the web (2), which has a transmitter (8) for a monitoring beam (12) directed onto the web (2) and a receiver (9) for a return beam (13) returning from the path (2) and which is connected to a signal processing device (11), by means of which the distance between the emission of the monitoring beam (12) and reception of the reflection beam (13) can be measured and in the case one that exceeds a predetermined bandwidth A control pulse can be generated at a distance, characterized in that the signal processing device (11) is designed as a computer provided with an input for a web speed signal, which is programmed such that a different, preferably larger bandwidth (B) is set before the speed signal arrives, than after the arrival of the speed signal. Apparatus according to claim 6, characterized in that the computer forming the signal processing device (11) is programmed in such a way that at least the distance between the web (2) and the sensor (10) when the speed signal arrives is measured and this distance as the center of that after the arrival of the Speed signal adjustable, smaller bandwidth (b) is adjustable. Device according to claim 6 or 7, characterized in that each sensor (10) has an ultrasound transmitter (8) and ultrasound receiver (9). Device according to one of the preceding claims 6 to 8, characterized in that the machine drive can be switched off and / or a web catching device (5) and / or web separating device can be activated by means of the signal processing device (11) .

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