DE2141741A1 - CALENDING ROLLER DEVICE WITH A DEVICE FOR DETERMINING THE THICKNESS OF THE MOLD AT THE NAP - Google Patents

Description

Krauss-Maffoi TK i45 Corporation

Calender roll device with a device sub sensing the thickness of the kneading & m roll gap

Di · invention relates to a · Kalanderwalsenvorrlchtung sur continuous production of viscous "Bandna" TERIAL, in particular plastic film, "it ®tusr A" direction "UBJ detecting the thickness dee Kn®ts em orphan gap by scanning ·

The thickness of the knot at the orphan gap of calenders in plastic film production is so low for the quality of the Tolie as it is for the safety of the calender legacy » Drive is of decisive importance · If you drive with too thick kneading, there will be accumulations of material on its periphery facing away from the roller gap which is withdrawn from the continuous material circulation in the kneading, cools and is only caught by the roller gap after a certain time · Da »undercooled Material constitutes areas of inferior quality in the finished film, which can only be used with one operation less kneading thickness, since then the whole era "does" fc "rial continuously is transported,

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The lower the kneading thickness, taking into account the high quality of the film, the greater the risk of the rolls collapsing in the event of gilnz-11 cheat. so that with the usual observation of the putty by an operator, the movement of the vials, initiated by k this: in such fillings, may start late and the vals touch each other directly. Such a Valzenborüferuag equips the Yalsenoberflttohe, which requires a shutdown of the calender as well as a machining of the orphans to restore the surface elite and precision "is the kneading, it al ~ the quality requirements for the film allow only driven around the rollers aussusehließen Aufeinanderiahren the bidders.

A known calender roller device dui- oin ^ i ι; ; called type sees «was an automatic htjgeLunr, the Xnetdicke by regulation of the cleavage. / or, auai report the kneading thickness eoll ainu lo

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term probe has been used, which is located on the surface of the rotating knot close to the center · Naturally, there is direct mechanical scanning of the modeling clay undesirable, for example because they can lead to a disturbance of the rotation.

The invention reads the task migrund «, a® calender roll device indicate the "in b®rüh" rungßloeee recording the thickness of the knead on the through " Management of an automatic operation of the Kalaasdcre with optimal kneading thickness allowed and one touch the rollers can be safely locked «

The object is achieved according to the invention in that a coherence radiation source, in particular a laser, and a photodetector are provided as limptHngmr and that the non-diverging beam of the radiation source directed at the receiver is essentially axially along the surface of the clay facing away from it runs "

The Taatstrahl is either through the kneading Pfän ^ he shielded, eo that this kssin emits, or the jet hits the recipient unhindered due to the slight kneading diclce, whereby a chip «·

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nungeaignal is generated Deageaäe is the Einrieh tune ■ ** ■ Find out the kneading thickness of the invention Device eo «η mounted on the Valsen bearings that the Taetetrahl the optimal thickness dee offers » ■ o that there is a voltage signal KU thin knot and deeeen staying outside a Hu thick inet elcnelieiert "D * e 6ign * l is the rule" ug "· leads. The scheme realizes or reduces the dea V & lsensp «.lt and dealt de« Xn * t quoted mead »tore 1-quantity» Je naohdea »whether the signal erasure« is not possible not, eo defl the clay la veelichen constant DIk * does not have the signal before a beetle «- ten time intervals, the lungs of the Valsendreh eahl dependent let, aneehen, eo can be independent of The supply of material has a time relay as a result of the preparation the Valsen came apart depending on the speed and the IfydraulilcdrttOk of the possibly existing Valsenblegevorriohtung can be reduced to KuIl «Zueatslioh an akuetiechoe signal can be given «

Ia comparison with the well-known aeohaniechen abtaetung dos Xeet · shows "loh the Irfaeeweg of the kneading thickness by the whale axially running Taetetstrahl with more than 4in the gap length uneven formation of the clay *""- * eentlleh more coaplex"

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The use of miner carbon radiation source for a niohtdlvergierondsn tactile beam offers the advantage over 9 ± n <3T normal light sources that the Taatstrahl, due to its sharpness and intensity, dsas ¥ eiehnaehezL ^ äiDpfe _e the always di @ dure® environment of the knot ®a ₉ in e®in®as bus receiver practically not so that an erroneous «or not nal & leveling is excluded ·

More information about the change in the Kn®t @ will be available oäfi one? distributable design by »rhalton that« in · heelifrequent · Pendelsehvin * gong de · Tastetstrahlβ in a eur YalEonaeheen level ic vertical plane is provided and the recipient has a correspondingly long distance © Εκρ— has sensitivity zone.

Through the use of a receiver with an elongated Eapfindliohkeitsaone, on which the probe beam swings back and forth, a pulse voltage of constant frequency is generated, whereby the length of the pulses and thus the mean value of the signal voltage of the thickness of the clay is inversely proportional to the signal voltage reflects al ·· in «in« «determined by Aim LäR ^ e

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and arrangement dee predetermined receiver RE-rich, the Knetdicke again _e van gleichliomnb a Knetmessung. Such a "signal," which continuously changes with the kneading thickness, allows a longer control of the process, since the "extent of the deviation of the kneading thickness from your target" is determined, and also "through integration and subsequent differentiation of the signal The speed of the change in the putty can be entered into the prosefl rule, which is indispensable for the decision, for example, whether in the case of sibBssJhmender Knetdick an increase in the M & $ * T & mtawfnhT _$ b © i * piel "how" ie "by Br * itenveretellunc der Rundeieaeer the Streif "Kaohneidverrieh" tune of a Miach whale plant maintained in Terfee, is still sufficient to avoid the orphans being approached, or whether the rollers must already be moved apart ·

Finally, the choice of a coherence radiation source for the kneading thicknesses envisaged here proves measurement as particularly valid, since a measurement in Much larger skin can be falsified by the radiation-absorbing WsiabJBaoherdlUipfe, than ice kneading monitoring, which is only awei strongly lower ocei ** "*!" Incidents should be slgnalisisrea.

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So that the signal voltage does not depend too much on the The thickness of the knots on the side facing the radiation source depends on and on the other hand increases large distance between the end of Vala © 0 and the Radiation source can be chosen nmO, is in ¥ © itar « Formation of the invention an oscillation of the probe beams parallel to the calibration itself «, this guarantees that any change in the Knetdlek® regardless of whose position has the same influence on the spamnangs «« signal is.

The scanning beam oscillating in parallel has the further advantage that a change in the nominal kneading thickness does not necessarily require a spatial shift of the radiation source and limp finger, &&. me In most Γίίΐΐβη it should be sufficient to put the "/ erMaderten signal setpoint" value in the ProBoss control

¥ Uhrend the Strahlpendelung by high frequency ©© Ver »sclivenlcon the radiation source, reflection of the beam to a vibrating plane mirror or einoin ro» tierendon POL3 ^r gonspi @ gel or by ZifisehenBChaltung a rotating Prisiaae unavailable ", the parallel resonance Alone T except by corresponding par · - oscillations of the radiation source advantageously by a switched into the beam, torsional oscillation

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Plane-parallel, radiation-permeable plate placed on the surface with adjustable amplitude can be generated. To choose the level of the oscillation frequency iet eo, that a sufficient difference to the possible frequency of kneading thickness changes is guaranteed

Since during the start-up phase of the calender no Kneading is formed at the roller gap, the device for detecting the Inet thickness may be during this time rough »not be switched on in the control loop» as it would cause the roller actuators to be switched off. A secure Xalander operation requires However, even during this phase, a device, bit the help of which a direct contact of the rollers is reliably avoided. Accordingly, a preferred one Embodiment of the invention characterized in that in addition to detecting the roller gap during During the start-up phase, one coherence radiation source each directed towards the roller gap and one on the one facing away from the radiation source in the area of both roller ends Each side is provided with a photodetector arranged in the beam axis as a receiver, with between these receivers and the receiver of the device for detecting the kneading thickness a changeover switch is switched on.

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The toggle switch enables initial monitoring of the nip only, from which it expires the start-up phase, i.e. after the formation of putty, a switch is made to the monitoring of the putty thickness The two beams for monitoring the gap have a cross-sectional area, the extent of which is perpendicular to the gap, a continuous decrease in the Si « signal tension "guaranteed with decreasing roller gap" When a certain signal tension minimum is reached, the target roller gap is arranged, the whale nose actuators are switched off. Furthermore, the hydraulic cylinders of a possibly provided whale bending device not with pressure can be acted upon · Switching from the roller gap « Monitoring on the monitoring of the kneading thickness can be from Can be done manually as soon as sufficient kneading has developed · However, it is also possible to provide an automatic switchover · This can be done in certain temporally dependent on the achievement of the roll target gap can be made. It is also possible to take the device for detecting the kneading thickness already during the start-up phase and with it to the changeover mechanism outside of the changeover switch in order to trigger an automatic changeover when a previously inert kneading thickness is reached.

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The invention is explained below on the basis of exemplary embodiments explained in more detail with reference to the drawing.

It shows)

1 shows a partial view of a calender roller device according to the invention eit a device for detecting the kneading thickness in a schematic Representationι

Whistle. 2 a coherence radiation source with a

oscillating ehmnmn mirror for generating a Taetstrahlpendelung in a schematic representation;

3 shows a liotiaxena-Stveailungsqnollo iait a drive device for generating a tactile beam parallel oscillation in a schematic representation;
_h Fig. h a coherent ^ radiation source with a

oscillating plane-parallel plate for generating a Taatetstrahlpa, parallel oscillation in schematic representation}

a toilet not a calender roll device according to the invention iait a device for capturing the ¥ alzenspaltstUrlco in scliematißcher Representation and

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6 shows a block diagram of the linkage of the receivers of the monitoring equipment with the Re ge! circuit gur control dee ¥ alzpr © g © ss * s.

A coherence radiation source 1 on the one hand and a photodetector as a receiver 2 attached to the roller bearings 3 of a calender roller device diagonally opposite the roller gap asadan (Fig. 1) The sharply focused probe beam 5 of the radiation source 1 is sensitive to the sensitivity 6 addressed to the recipient, with the exact L & £ @ dated. Radiation source and the receiver 2 is beetisant characterized "that the pushbutton" radiant valzenaxial along the au6er © n surface of the desired Knets h to extend the nip so that he k at too small a kneading impinges on the receiver and if too much kneading h from the receiver is shielded . The receiver generates a signal voltage which is fed to the control circuit 7 (FIG. 6) for the rolling process. The control circuit (7) acts, among other things, on the roller drives and part drives, a roller bending device, a strip cutting device of an upstream Misoh rolling mill as well as signaling devices for acoustic and optical signals »

The radiation source 1 also has a drive 8 _t with the aid of which the Taetstrahl 5 in a high-frequency pendulum oscillation around its surface

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Pendulum angle «c can be offset, whereby the pendulum oscillation cbeno reads perpendicular to the roller axis plane. Correspondingly, the sensitivity zone 6 of the receiver 2 to which the oscillating Taetstrahl is directed, ribbon-like shape. at With the drive switched on, a pulse signal voltage of constant frequency is generated in this way other than when the Taatstrahl is at rest, in which the signal * voltage can assume the values zero or U, has an average value that is between a maximum can change continuously in the absence of kneading and the value zero with extremely strong kneading. Bern clay clay is assigned an average voltage value · The practically punctiform moving impact zone of the Beams on the receiver basically require a receiver structure consisting of a large number of photocells arranged in a row and electrically connected in parallel, so that when the point of impact wander over This row of cells emits a constant voltage which, as a result of the partial shielding of the probe beam by the kneading, has a pulse character, the pulse length being inversely proportional to the kneading thickness.

A permanently mounted radiation source can of course also be used (Fig. 2) · In this

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In the case of the beam oscillation, for example, with Help * an oscillating plane mirror 9 in the beam «' gang reached

The one in Pig. Drive 10 illustrated 3 of the radiation "· source subjecting it to a Hin" motion "so that the Taetstrahl parallel to do even the initial position defined above oscillates" This "jet * is vibration according Pig x k with permanently mounted radiation source by switching a vibrating plane-parallel plate 11 achieved in the beam path.

One in Pig · 5 without the facility to detect the Gap monitoring device shown for kneading thickness consists of a coherence radiation source 12, which is arranged in the area of the two ends of the nip and is directed perpendicular to the nip, as well as a receiver 13 arranged behind the nip in the beam path. that while the orphans were racing in the start-up phase results in a continuously decreasing signal voltage. These signal voltages were input into the process control circuit 7 at the beginning of the calendering process. In the connections between the two receivers 13 and the control circuit 7, a change is possible. switch 15 is provided (Fig. 6), to which the Eoap-

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Catcher Z of the device is connected to record the kneading dough. The changeover switch ensures that either the signal voltages from the gap monitoring device or the signal voltage from the device for acquiring the kneading thickness goes into the control circuit. by hand »as soon as sufficient kneading has formed · Di * the dashed illustration in Fig. 6 shows a switching mechanism 16 to which the kneading thickness signal is applied and thus enables automatic switching when a kneading of a given thickness is reached ·

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Claims (1)

2U17A1 Ptitent Claims j 1.JKalanderwalsenvorrichtung aur continuous production of viscous strip material »in particular - plastic film, with a device for detecting the thickness of the dough at the nip by scanning, characterized in that a coherent» radiation source (1), in particular a laser, and a photodetector is provided as a receiver (2) and that the non-diverging beam (5) of the radiation source (1) directed at the receiver (2) runs essentially axially along the surface of the putty (h) facing away from the roller gap. 2. Calender roll device according to claim 1, characterized in that a high-frequency pendulum oscillation The test jet (5) is provided in a plane that is essentially perpendicular to the plane of the roller axis and the receiver (2) has a correspondingly elongated sensitivity zone (6). ο K & landerw «lKen device according to. Claim 1, thereby 309808/11 11-16 - 2ΗΊ7Α1 characterized in that a high-frequency parallel oscillation of the probe beam (5) in a bone to the roll axis substantially vertical plane is provided and the receiver (2) a corresponding elongated sensitivity zone (6) having. 4. Calender roll device according to claim 2, characterized in that a high-frequency oscillating plane mirror (9) is switched on in the key beam path _{o to generate the beam oscillation} 5. calender roll device according to claim 3 »characterized in that for generating the beam parallel oscillation an adjustable swiveling, plane-parallel, radiation-permeable plate (11) is switched on in the key beam path. ^ - 6, Calender roll device according to one of the preceding claims 1 to 5, characterized in that in addition to the detection of the roller gap during the start-up phase, in the area of both roller ends each a coherence radiation source (12) directed towards the roller gap and on the one facing away from the radiation source A photodetector arranged in the beam axis since the roller gap 309808/1111 - 17 - 2H1741 all receivers (13) are provided, with between these receivers (13) and the recipient (2) of the A toggle switch (15) is switched on to detect the kneading thickness. 309808/1111 At Blank page