The present application claims priority under 35 U.S.C. §119 of German Patent Application No. 10 2004 046 795.1 filed on Sep. 27, 2004, the disclosure of which is expressly incorporated by reference herein in its entirety.
1. Field of the Invention
The invention relates to a machine for producing and/or treating a material web, in particular of paper or board, in which the material web can be guided along a material web guide path by means of at least one material web guide device from a material web production section or material web input section, in order to pass at least one material web treatment device, having an apparatus for forming a transfer strip of the material web and transferring the transfer strip through the machine, it being possible for the material web to be transferred along the material web guide path in that, by means of the apparatus for forming and transferring the transfer strip, a leading transfer strip of the material web is formed and guided through the machine, and the width of the transfer strip is increased to the full material web width (what is known as “tail widening”), and having an apparatus for detecting a break in the material web.
The invention relates further to a method for monitoring the transfer of a material web of paper or board along a material web guide path of a machine for producing and/or treating the material web, the transfer of the material web being carried out in that a leading transfer strip of the material web is guided through the machine and the width of the transfer strip is increased to the full material web width (what is known as “tail widening”).
2. Discussion of Background Information
What is known as web threading in a machine for producing and/or treating a material web, specifically a material web of paper or board, is normally carried out by means of at least one transfer strip, which is divided off from the material web and is then guided through following guide and/or treatment devices. This type of web threading is standard both in papermaking and boardmaking machines having in each case at least one head box, a wet end (in particular wire section and/or press section), and a drying section, possibly one or more processing sections (for example a coating section) and also in paper or board processing machines provided for the off-line treatment of a material web produced in another way, for example what are known as coating machines. In order to form or divide off the transfer strip, diverse devices are known. For example, what are known as strip knock-off devices, water jet cutting devices, laser cutting devices and so on are used. In connection with papermaking machines, use is normally specifically made of what is known as a “couch jet” which, on a wire of the wire section, cuts a strip into the paper web (or board or tissue web), which is then guided through the further sections of the machine, in particular at least one press section and at least one drying section and, if appropriate, at least one treatment section. In the case of transfer devices which are mounted downstream of the drying section, what is known as a tip cutter is used instead of the couch jet. As soon as the transfer strip is running stably through the machine, it is then possible, by using the couch jet on the wire, to move to the “full width”, that is to say approximately from a strip position adjacent to the operator side to the drive side or, vice versa, from a strip position adjacent to the drive side to the operator side, as a result of which the full web width then automatically runs through the machine. In the specialist field, one speaks of what is known as “tail widening” in this connection. This type of web threading or similar type of web threading (for example, the transfer strip could also be formed in a central region of the material web) has also proven worthwhile in relation to all the conventional material web treatment devices, those designed as an online material web treatment device and designed as an off-line material web treatment device, such as press sections, predryer sections, afterdryer sections, coating machines, smoothing units (for example calenders), reelers and so on.
However, existing web break detection systems only monitor the “normal operation” for a web break, specifically when the material web has already been threaded. Various types of web break detector are known, for example based on detecting the web speed (cf., for example, DE 101 57 914 A1), the detection of a temperature change (cf., for example, DE 101 31 281 A1), the optical detection of surface characteristics (cf., for example, DE 201 03 070 U1 and DE 42 16 653 C2) and the detection of pressures or pressure changes in connection with a vacuum web guiding device, in particular suction roll (cf., for example, EP 0 660 898 B1 and DE 100 31 163 A1). Conventionally, break monitoring is therefore not effective or is deactivated during tail widening. If a break occurs during tail widening, this must be detected by the operating personnel and it is then necessary for all the measures to be initiated manually in order to avoid damage to the machine and in order to be able to re-thread (to transfer) the material web. This applies in spite of the fact that, in modern papermaking machines, the aim is generally to increase the production efficiency. What stands in the way of automatic web break detection is the thought that the introduction of the transfer strip into the machine and tail widening are transient, not steady state, processes or states, which should be monitored better by human beings for greater reliability.
Surprisingly, it has been shown that, even in connection with the transfer of the transfer strip and, above all, in connection with the tail widening, automatic, machine-based monitoring for the occurrence of a web break can be carried out with high reliability. For the machine mentioned at the beginning, according to a first aspect of the invention, it is accordingly proposed that the apparatus for detecting a break in the material web be provided and designed for the purpose of responding to a break in the transfer strip or the material web during the transfer of the material web, in particular during the increase in the width of the transfer strip. In relation to the method mentioned at the beginning, the invention proposes that, during the increase in the width of the transfer strip, monitoring for a break in the transfer strip or the material web is carried out.
On the basis of the invention, failures during web threading, specifically during tail widening, can be detected automatically and therefore quickly, and a re-start of the web threading and tail widening can be introduced quickly and automatically. The transfer times occurring over the operation of the machine can be reduced in this way, which means that a higher level of productivity is reached. The automated monitoring and, if appropriate, initiation of suitable reactive measures is also advantageous inasmuch as damage to machine components as a result of a web break can be avoided, in particular by triggering web knock-off in the event of a web break. Furthermore, as already mentioned, thought is above all also given to all the necessary reactive measures being initiated automatically in response to the detection of a web break, in order to be able to re-transfer the material web. For example, by activating the appropriate actuators, for example vacuum breaker valves can be closed, the couch jet or, generally, a transfer strip forming device can be moved to the strip position, fan rotational speeds can be lowered, to name only a few examples. The web transfer can therefore be carried out more quickly and more successfully. The initiation of appropriate measures (knocking off the web and preparing the renewed web transfer) manually by the operating personnel can be dispensed with.
If the tail widening was successful, that is to say no break occurred during the transfer of the transfer strip and during the tail widening, then a change can expediently be made automatically to “normal operation”, in which the conventional break monitoring can then be carried out, for example in accordance with the solutions from the prior art mentioned above.
Thought is above all given to the apparatus for detecting a break in the material web being designed for the purpose of responding to a break in the transfer strip or the material web on the basis of at least one detection variable representing the width of the transfer strip, directly or indirectly. As based on the method according to the invention, provision can accordingly be made for monitoring for a break in the transfer strip or the material web to be carried out on the basis of at least one detection variable representing the width of the transfer strip, directly or indirectly.
The development proposal is based on the thought that the width of the transfer strip at a given position along the material web guide path is a measure of the progress of the tail widening. In the case of successful web threading, the width of the transfer strip at a reference position must correspond to the width of the transfer strip at the location of the formation of the transfer strip at a preceding time depending on the web running speed. If, by means of appropriate activation of the couch jet or, generally, the device for forming the transfer strip, provision is made for the transfer strip to become continuously wider during tail widening, this must also apply at another point along the material web guide path, as long as the web threading is carried out properly and, in particular, no web break occurs.
In principle, all the web break detection and monitoring techniques known from the prior art are suitable in connection with the break detection and monitoring according to the invention. For example, the apparatus for detecting a break can for example have an optical detection arrangement in order to detect a web break or to provide the detection variable. As based on the method according to the invention, it is proposed that the monitoring be carried out on the basis of optical detection, in particular optical detection of the width of the transfer strip. Furthermore, the apparatus for detecting a break can have a temperature detection arrangement, in order to detect a web break or to provide the detection variable. As based on the method according to the invention, it is proposed that the monitoring be carried out on the basis of detection of temperature values.
By contrast, provision is particularly preferably made for the apparatus for detecting a break to have a pressure detection arrangement or pressure change detection arrangement, in order to detect a web break or to provide pressure values as detection variable. In relation to the method according to the invention, it is proposed as particularly preferable that the monitoring be carried out on the basis of detection of pressure values or pressure change values or a pressure change.
Advantageously, in each case at least one dedicated pressure detection arrangement or pressure change detection arrangement can be provided for a plurality of sections of the machine, for example a plurality of drying groups or other treatment devices, in order in each section to detect a web break immediately and therefore with very quick reaction in each case or to provide pressure values as detection variable for the web break detection.
In connection with these development proposals, thought is above all given to the pressure detection arrangement or pressure change detection arrangement being designed and arranged for the purpose of detecting at least one instantaneous operating pressure of at least one vacuum device acting on the material web or the transfer strip. For example, thought is given to what is known as a suction roll, which is used for material web guidance and, possibly, web deflection. Alternatively or additionally, a or the pressure detection arrangement or pressure change detection arrangement can be designed and arranged for the purpose of detecting at least one instantaneous operating pressure of at least one positive pressure device acting on the material web or the transfer strip. In this connection, thought is given, for example, to what is known as an air turn, which is used for non-contact web guidance and, possibly, web deflection.
Based on the method according to the invention, it is proposed that at least one instantaneous operating pressure of at least one vacuum device or positive pressure device acting on the material web or transfer strip be detected.
The background to these development proposals is that, during tail widening, the vacuum device or positive pressure device is increasingly covered by the transfer strip becoming wider or the material web becoming wider, which, in a vacuum device increases the vacuum as a result of an air stream becoming smaller, that is to say reduces the prevailing operating pressure, and, in a positive pressure device, because of increasing throttling of the air discharge, increases the positive pressure, that is to say can increase the operating pressure. The operating pressure prevailing in the vacuum or positive pressure device to this extent reflects the width of the material web or of the transfer strip on the device.
As a rule, it will be expedient if the relevant vacuum device or positive pressure device is provided in any case, in order at least to participate in the guidance of the material web or of the transfer strip as part of the material web guide device.
The vacuum device can comprise at least one suction roll and/or at least one suction box and/or at least one vacuum transport belt. The positive pressure device can comprise at least one blower roll and/or at least one blower box and/or at least one air turn.
As particularly preferred, it is proposed that at least one pressure sensor of the pressure detection arrangement be arranged in the/a suction box or blower box. In the case of a suction roll, the pressure sensor is preferably arranged in a suction box assigned to the suction roll. As compared with a solution known per se, in which the pressure sensor is provided in a line connecting the suction box to a vacuum source, this offers the great advantage that high pressure fluctuations occurring acyclically, the cause of which has not yet been fully explained, can be avoided. The problem of measuring the pressure in a suction line could be that the pressure measurement is influenced by the flow velocity of the air. Influences of this type are avoided if the pressure is measured in the suction box. More reliable monitoring of the transfer of the material web and, generally, more reliable break monitoring are achieved.
If the suction box comprises a transfer suction zone which is assigned to the transfer strip and an operating suction zone which, together with the transfer suction zone, is assigned to the full material web width and which is connected or is able to be connected via the transfer suction zone to a vacuum source, then the pressure sensor is preferably arranged in the operating suction zone. Between the transfer suction zone and the operating suction zone, at least one connecting opening or connecting line that can be closed by a valve flap or the like can be provided and, for the pure introduction of the narrow threading section of the transfer strip, is closed, in order to be able to attract the latter with sufficient vacuum. For the tail widening, this connecting opening or connecting line is then opened, in order to be able to monitor the proper widening of the transfer strip or the material web via the operating pressure.
The machine can advantageously have an evaluation unit which is designed for the purpose of comparing detected pressure values or consequential values depending on the latter with one another and/or with at least one predefined reference value and of outputting a break signal when at least one break condition is fulfilled. On the basis of the break signal, the reactive measures mentioned can then be initiated and the break can be signaled to the operating personnel. Based on the method according to the invention, it is proposed that detected pressure values or consequential values dependent on the latter be compared with one another and/or with at least one predefined reference value in order to determine the fulfillment or non-fulfillment of at least one break condition.
Thought is above all given to the evaluation unit being designed for the purpose of comparing the magnitude of pressure values or consequential values corresponding to the latter recorded successively in order to check a break condition, the break condition being fulfilled when the values deviate from a predefined reference curve. In relation to the method according to the invention, it is accordingly proposed that, according to one break condition, pressure values or consequential values corresponding to the latter recorded successively be compared with one another, and that the break condition be determined to be fulfilled when the values deviate from a predefined reference curve.
According to an expedient embodiment, the break condition is fulfilled when, in the case of a vacuum device, a pressure value that is assigned to a later time is greater than or equal to a pressure value that is assigned to an earlier time or, in the case of a positive pressure device, a pressure value that is assigned to a later time is less than or equal to a pressure value that is assigned to an earlier time. Based on the method according to the invention, it is proposed that the break condition be determined to be fulfilled when, in the case of a vacuum device, a pressure value that is assigned to a later time is greater than or equal to a pressure value that is assigned to an earlier time or, in the case of a positive pressure device, a pressure value that is assigned to a later time is less than or equal to a pressure value that is assigned to an earlier time.
This embodiment of the evaluation unit and the method is expedient and reliable when the pressure values or consequential values compared with one another are assigned to times which, as based on the web speed and the rate at which the transfer strip or the material web is widened, have a certain minimum spacing in time, so that in the event of a successful, proper curve, it is always ensured that for increasing times the operating pressure falls (in the case of a vacuum device) or rises (in the case of a positive pressure device), which, in the case of processing consequential values derived from the pressure values, applies appropriately to these. If, on the other hand, an evaluation of pressure values or consequential values lying closer to one another in time is provided, then, on account of relatively small pressure fluctuations which may possibly occur, this could lead to the detection of a break although such a one has actually not occurred. In order to avoid such erroneous detection, it is possible for a tolerance band, for example expressed by a threshold value, also to be included in the comparison. In this regard, it is proposed in practical terms that the break condition be fulfilled when, in the case of a vacuum device, a pressure value assigned to a later time exceeds a pressure value assigned to an earlier time by a predefined threshold value or, in the case of a positive pressure device, a pressure value assigned to a later time falls below a pressure value assigned to an earlier time by a predefined threshold value. Based on the method according to the invention, it is accordingly proposed that the break condition be determined to be fulfilled when, in the case of a vacuum device, a pressure value assigned to a later time exceeds a pressure value assigned to an earlier time by a predefined threshold value or, in the case of a positive pressure device, a pressure value assigned to a later time falls below a pressure value assigned to an earlier time by a predefined threshold value.
According to a particularly expedient development, the evaluation unit is designed for the purpose of comparing detected pressure values or consequential values dependent on the latter with a predefined reference value, in order to check a tail-widening finished condition which is fulfilled when the pressure value reaches a threshold value corresponding to the reference value. In relation to the method according to the invention, it is proposed that detected pressure values or consequential values dependent on the latter be compared with a predefined reference value, in order to determine the fulfillment or non-fulfillment of a tail-widening finished condition, which is determined to be fulfilled when the pressure value reaches a threshold value corresponding to the reference value.
On the basis of the fulfillment of the tail-widening finished condition, the apparatus for detecting a break in the material web can be changed over to a normal operation monitoring mode, in which monitoring for the occurrence of a web break can then be carried out in a conventional way.
Thought is specifically given, in the case of a machine with a plurality of sections (in particular a plurality of drying groups and material web treatment devices) in each case monitored separately for a break during the increase in the width of the transfer strip, to changing to the normal operation monitoring mode in each case separately for the respective section when the fulfillment of the tail-widening finished condition is determined for this section. Conventional break detection systems are activated only when the material web has been widened completely over the entire machine.
It has already been mentioned that the machine can expediently be designed for the purpose of initiating at least one reactive measure automatically in response to the detection of a break in the material web, in order to avoid damage to the machine as a result of the break and/or to prepare for a renewed transfer of the material web. The reactive measure provided can be one or more of of the following measures: triggering a web knock-off, setting machine components into a waiting or safe state, activating the positive pressure or vacuum device for the renewed transfer of the material web, activating the apparatus for forming and transferring the transfer strip for the renewed transfer of the material web.
According to the first aspect, the invention also provides an apparatus for implementing the method according to the invention, for example for providing a machine according to the invention, for example by equipping or retrofitting a machine as mentioned at the beginning.
According to another (second) aspect, the invention further provides a machine for the production and/or treatment of a material web, in particular of paper or board, in which the material web can be guided along a material web guide path by means of at least one material web guide device from a material web production section or material web input section, in order to pass at least one material web treatment device, having an apparatus for detecting a break in the material web on the basis of a detected operating pressure of a vacuum device having a suction box.
According to the invention, provision is made for at least one pressure sensor for detecting the operating pressure to be arranged in the suction box. It has been shown that a pressure sensor arranged at this point can respond particularly reliably to pressure changes resulting from a web break. The same applies to web break detection in conjunction with the threading or tail widening of the material web according to the first aspect of the invention. Furthermore, on the basis of the pressure detected here, a diagnosis of components of the vacuum device or of an associated vacuum source (for example a fan arrangement) can be carried out particularly reliably. Erroneous detections of a break and erroneous diagnoses relating to such components are avoided in this way. If the suction box has a transfer suction zone which is assigned to the transfer strip and an operating suction zone which, together with the transfer suction zone, is assigned to the full material web width and is connected or is able can be connected via the transfer suction zone to a vacuum source, it is preferred for the pressure sensor to be arranged in the operating suction zone.
With regard to the machine and the apparatus according to the first aspect of the invention, reference should further be made to the following. The evaluation unit can be constructed on the basis of an electronic computer unit, in particular a microprocessor arrangement, on which there runs an evaluation program which has software functionalities providing the comparison of the values and the testing of the various conditions. With regard to the values to be compared, it should be pointed out that it is not absolutely necessary for original pressure measured values to be processed but that values or data derived from these, the “consequential values” mentioned above, can be processed in order to test for the break condition or break conditions and the tail-widening finished condition. It is also possible for electrical signals to be compared with one another as the pressure or consequential values mentioned, for example measuring sensor output signals or converter output signals, for example output signals from a P-I converter without conversion into pressure values, possibly even in an analog manner not providing any digital to analog conversion.
Within the context of the invention, in addition to the criteria and characteristic values mentioned directly here for the instantaneous state during the tail widening or the occurrence of a break, other criteria and characteristic values can also be used, in particular including the criteria and characteristic values quoted in the publications mentioned above. Reference is made in particular to the documents DE 101 31 281 A1, DE 201 03 070 U1, DE 42 16 653 C2 and EP 0 660 898 B1.
According to the invention, monitoring both of the normal operation of the machine and at least of the tail widening during the web transfer (web threading) is possible and provided. Developing this, thought is also given to monitoring the transfer of the transfer strip or its threading section with regard to a break automatically as well, for example on the basis of the known detection techniques mentioned.
The present invention is further described in the detailed description which follows, in reference to the noted plurality of drawings by way of non-limiting examples of exemplary embodiments of the present invention, in which like reference numerals represent similar parts throughout the several views of the drawings, and wherein:
The invention will be explained in more detail in the following text using exemplary embodiments shown in the figures, in which:
To provide the break monitoring according to the invention, for each group of drying cylinders 14, at least one vacuum device 18 is equipped with an apparatus for detecting a material web break, which will be described in more detail later.
To dry the material web 12, this is introduced into the system comprising drying cylinders 14 and vacuum devices 18 such that it is guided on the drying cylinders 14 pressed between the dryer felt 16 and the surface of the drying cylinder 14, while it runs around the vacuum devices on the outside on the dryer felt 16.
When the machine 10 is started up, following the feeding of a new material web or after a break in the material web, it is necessary to re-introduce a leading transfer strip of the material web into the roll system of the drying section and, in the process, to transfer it alternately between a drying cylinder 14 and a vacuum device 18. In order in this case to deflect the transfer strip deflected on the outside on a vacuum device 18 counter to the force of gravity and feed it to the following drying cylinder 14, the vacuum devices 18 are connected to a vacuum source, at least during the transfer operating state of the machine, so that the vacuum device 18 forces the transfer strip onto the predefined material web path by means of suction.
The transfer strip is generally cut directly out of the material web automatically before the threading of the material web, by using a suitable device, for example what is known as a couch jet. A device of this type can, for example, comprise a cutting device that can be displaced transversely with respect to the running direction of the material web, for example a water jet or laser cutting device, a circular knife or the like or what is known as a strip knock-off device. During the cutting or the formation of the transfer strip, the material web moves in the running direction. In the following text, the use of a couch jet in a papermaking machine will be assumed. The couch jet is initially in a strip position and cuts a narrow frontmost section of constant width as a threading section or else a ribbon, which is guided through the machine by means of suitable guide means. Following a specific advance distance of the material web, the couch jet is moved uniformly in the direction of the opposite edge of the material web and thus cuts the transfer strip with preferably uniformly increasing width, until it reaches the full width of the material web and the cutting of the transfer strip has been completed. In the process, the material web moves continuously onward and is threaded into the paper machine.
A vacuum device 18 provided for use in a paper machine according to the present exemplary embodiment and serving as a vacuum deflection device, having an apparatus for detecting a material web break, will be explained in more detail in the following text with reference to
If a vacuum is generated and maintained in the suction box 24 and in the suction roll 22, this vacuum is propagated through the drilled holes 30 of the suction roll 22 that are currently not opposite the suction box 24 and through further openings 32 in the suction box 24 to the outside and through the porous dryer felt 16 running around the vacuum device 18, and attracts by suction a material web section to be deflected at the vacuum device 18, in particular a transfer strip to be transferred, in order to hold the latter on the material web guide path and feed it to the following drying cylinder 14.
A valve 34 and a dividing wall 36 are also indicated in
The front threading section of the transfer strip is followed by a further section, in which the width of the transfer strip increases continuously, until the transfer strip ultimately reaches the full width of the actual material web and, at this point, merges in one piece into the actual material web or is connected to the latter. The operating state of the paper machine in which the continuously widening transfer strip is transported is designated “tail widening” of the material web. During the tail widening of the material web, the valve 34 is opened and an approximately uniform vacuum is built up both in the transfer suction zone 38 and in the operating suction zone 40 and in the suction roll 22. This vacuum which builds up is counteracted by the air taken in, which is taken in through those drilled holes 30 and those openings 32 which are not yet covered by the transfer strip. The pressure established in the suction box 24 accordingly depends on the number of openings 30 and 32 not covered by the transfer strip, given a constant suction power of the vacuum source. This number decreases continuously with increasing width of the transfer strip, so that the air stream entering the suction box 24 from outside and counteracting the evacuation of the suction box 24 also decreases. With increasing width of the transfer strip, the pressure within the suction box 24 thus decreases, until it reaches a minimum value after the complete tail widening of the material web. The operating pressure p in the suction box 24, decreasing with the width of the transfer strip, is illustrated schematically in the graph of
The apparatus according to the invention for detecting a break in the material web uses the curve previously described of the pressure within the suction box 24 during the tail widening of the transfer strip of the material web in order to monitor correct tail widening and, in particular, to detect the occurrence of a break in the transfer strip. For this purpose, in the suction box 24, more precisely in the operating suction zone 40 of the suction box 24, a pressure sensor 42 which detects the pressure in the suction box 24 is arranged. The pressure sensor 42, as shown in
The pressure sensor 42 is connected to a P-I converter (pressure-current converter, not shown), which outputs a current signal representing the magnitude of the measured pressure to an electronic control unit (not shown). The electronic control unit can also be supplied a position signal, which indicates the travel position of the couch jet transversely with respect to the running direction of the material web. From the speed of the material web and the distance from the couch jet as far as the monitoring vacuum device, an instantaneous reference web width of the transfer strip at the monitoring vacuum device can then be determined in the electronic control unit or in a computing unit connected upstream, in order to provide said reference web width to the control unit.
The control unit is configured in such a way that, in a manner to be described in more detail later, on the basis of the instantaneous current value transmitted to it by the P-I converter and, possibly, also the instantaneous reference web width, it makes a decision as to whether there is a break in the material web, in particular its transfer strip, or not. The electronic control unit is also set up and implemented in the paper machine such that, in the event that a web break is established, it can initiate or carry out specific measures in reaction to the web break. In particular, thought is given to the electronic control unit being connected to a knock-off device, which knocks the material web off upstream of the break point in the event of a break, in order to avoid damage to the machine by winding operations and to prepare the web for new threading. As further measures, provision can be made to move the couch jet for cutting the transfer strip to a strip position, to transfer various device units of the production or processing sections into a waiting position, to move vacuum transport devices back or to initialize them (close vacuum breaker valves) or to indicate the occurrence of the web break to the operating personnel. Further measures which have to be taken upon the occurrence of a web break are obvious to those skilled in the art.
The electronic control unit according to the exemplary embodiment of the invention is further set up for the purpose of detecting the successful completion of the tail widening and outputting a corresponding tail-widening finished signal. As a reaction to this tail-widening finished signal, the paper machine can be changed automatically to a normal operating mode, in which for example a normal operating monitoring mode for the detection of a break in the material web is switched on, in which, for example, the break in the material web can be detected in a manner known per se. Further measures which have to be carried out when the paper machine is changed from the transfer and tail-widening mode to the normal operating mode are familiar to those skilled in the art.
With reference to
The pressure curve shown in
In order to detect a web break, in particular the following three design variants of a method for break detection can expediently be used.
In a first design variant, the reference pressure curve shown in
The magnitude of the threshold value can be set as a function of the magnitude of possible pressure fluctuations in the suction box 24, such that a random pressure rise, for example on account of short-term fluctuations in the suction power of the vacuum source or on account of short-term lifting of the material web at some points, does not lead to detection of a web break.
In the method according to the first design variant, the successful complete tail widening can additionally be detected by the fact that, for times t>t3, the measured pressure, apart from a threshold value, is equal to a pressure p3, that is to say a tail-widening finished signal can be output when the difference between the measured actual pressure and the reference pressure p3 falls below the threshold value.
The pressure p3 corresponds to an extremely small pressure when the material web tail is widened completely and which is also established during the normal operating mode. The pressure p3 should advantageously lie close to a minimum pressure pmin, which corresponds to the best possible evacuation of the suction box 24 and the suction roll 22 by the vacuum source. In most cases, however, the pressure p3 will be higher than the minimum achievable pressure pmin, since the material web will barely cover the openings 30 and 32 completely in a sealing manner (in particular also when a narrower material web is used) and certain leaks normally occur in the vacuum device.
In a second design variant, the electronic control device does not compare measured pressure values directly with reference pressure values from the reference pressure curve but compares two pressure values p4 and p5 recorded at different time t4 and t5 with each other. In the case of proper tail widening of the transfer strip, in accordance with the curve shown in
Furthermore, a third design variant for detecting a break of the transfer strip during tail widening is conceivable, in which the break is detected on the basis of the comparison of two pressure values p6, p7 recorded at a short time interval (at t6, t7). Although in this case, too, the use of a break condition according to the second design variant is in principle possible, it would be possible for erroneous triggering of a break signal to occur in the case of pressure measurements following one another closely in time, because of random pressure fluctuations within the suction box 24. As can be seen in
The aforementioned three design variants for detecting a material web break in the region of the profile strip can be combined with one another as desired, in order to provide the most optimal break detection possible. It is viewed as particularly preferred if the electronic control unit is continuously supplied with pressure values from the pressure sensor 42 (or the current values from the P-I converter representing the pressure values) and the electronic control unit monitors the instantaneously received pressure values continuously for a deviation from the reference pressure curve shown in
A combination of the above-described three design variants can also expediently be used in assessing tail widening which has been completed successfully, in order to generate the tail-widening finished signal. For example, a tail-widening finished condition can be used which indicates successful tail widening when the break conditions according to the design variants 1 and 2 have not been triggered and the pressure p reaches a reference pressure value p3 (third design variant).
The paper machine described in more detail above is to be understood as a preferred exemplary embodiment of the invention. Within the scope of the invention, it is not only possible for a continuous pressure drop (vacuum rise) in the suction box to be used as a monitoring variable for current tail widening of the transfer strip; instead it is also possible to monitor the continuous widening of the transfer strip with a large number of optical sensors or temperature sensors or the like arranged transversely with respect to the material web. In principle, the same electronic control device as has been described above in detail can then be used for various measuring methods, as long as a signal representing the instantaneous actual width of the transfer strip is supplied to it. In this connection, it should be underlined once more that the pressure variables (p1 to p7, see
Furthermore, it should be pointed out once again that the method according to the invention can also be applied to other sections of the paper machine, for example to the press section, the predryer and/or afterdryer section, to a coating machine, a calender, a reeler, etc.
It is noted that the foregoing examples have been provided merely for the purpose of explanation and are in no way to be construed as limiting of the present invention. While the present invention has been described with reference to an exemplary embodiment, it is understood that the words which have been used herein are words of description and illustration, rather than words of limitation. Changes may be made, within the purview of the appended claims, as presently stated and as amended, without departing from the scope and spirit of the present invention in its aspects. Although the present invention has been described herein with reference to particular means, materials and embodiments, the present invention is not intended to be limited to the particulars disclosed herein; rather, the present extends to all functionally equivalent structures, methods and uses, such as are within the scope of the appended claims.
Number | Date | Country | Kind |
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10 2004 046 795.1 | Sep 2004 | DE | national |