EP0137837A1

EP0137837A1 - Scraping device.

Info

Publication number: EP0137837A1
Application number: EP84901344A
Authority: EP
Inventors: Albert Wohrle
Original assignee: JM Voith GmbH
Current assignee: JM Voith GmbH
Priority date: 1983-04-02
Filing date: 1984-03-29
Publication date: 1985-04-24
Also published as: WO1984003847A1; FI844035A0; US4637338A; BR8406506A; IT1180024B; FI75286C; IT8467325A1; DE3311999A1; ES8501643A1; IT8467325A0; ES531138A0; DE3490083D2; JPS6238033B2; DE3464544D1; FI844035L; EP0137837B1; FI75286B; JPS60500943A

Abstract

Ce dispositif permettant d'enlever la pâte de couchage en excès comprend une racle sous forme de lame élastique (6) qui peut être utilisée seule ou en combinaison avec un rouleau racleur. La lame (6) est fixée sur un profilé de support (5) et peut être appuyée contre la laize de papier au moyen d'un listeau (7) également fixé sur le profilé (5). Le profilé (5) est pivoté (en 4) par ses deux extrémités sur des leviers (11) dont chacun est supporté (en 2) par un support (20). L'axe du palier (2) est aussi proche que possible de la ligne d'attaque de la racle (6). L'extrémité du levier (11) qui est éloignée du palier (2) est liée avec le profilé (5) par l'intermédiaire d'un organe de levage (10). Un mécanisme de pivotement (12) provoque le pivotement commun du profilé (5) et des leviers (11) par rapport aux supports (20) autour de l'axe du palier (2). Le mécanisme de pivotement (12) et les deux organes de levage (10) peuvent être rendus solidaires.This device for removing the excess coating paste comprises a doctor blade in the form of an elastic blade (6) which can be used alone or in combination with a doctor roller. The blade (6) is fixed on a support profile (5) and can be pressed against the paper width by means of a strip (7) also fixed on the profile (5). The profile (5) is pivoted (at 4) by its two ends on levers (11) each of which is supported (at 2) by a support (20). The axis of the bearing (2) is as close as possible to the attack line of the doctor blade (6). The end of the lever (11) which is remote from the bearing (2) is linked with the profile (5) by means of a lifting member (10). A pivot mechanism (12) causes the common pivoting of the profile (5) and the levers (11) relative to the supports (20) around the axis of the bearing (2). The pivot mechanism (12) and the two lifting members (10) can be made integral.

Description

Scraper

Technical field

The invention relates to a stripping device with the features that are specified in the preamble of claim 1. According to this, it is a device for stripping off excess coating slip from a running Warenoahn coated with the coating slip, e.g. Paper web. The stripping is carried out by means of a doctor blade which has an elastic blade. This squeegee can be made in two different forms: either it consists solely of the elastic blade. In this case, the blade itself is pressed against the web with its free end. Or the doctor blade is composed of a blade and a roller doctor blade attached to the free end of the blade. In this case, the roller squeegee is pressed against the web. In both cases, the blade is more or less deformed when pressed against the web.

The purpose of such a stripping device is to achieve a layer thickness that is as uniform as possible when coating a material web with coating slip. The layer thickness should be adjustable, for example by changing the force with which the doctor blade is pressed onto the web.

At the point where the excess coating slip is wiped off, the material web can run over a rotatable roller or over a fixed support device. Or the web runs between two symmetrically arranged stripping devices if it has been coated on both sides at the same time beforehand. State of the art

1. Wochenblatt für Papierfabrikation 1980, pages 781 to 783;

2. Pulp & Paper International, April 1976, pages 61-69;

3. DE-PS 24 35 521 = GB-PS 1 424 150;

4. Wochenblatt für Papierfabrikation 1980, pages 271 to 276

5. DE-PS 28 25 907 = US-PS 4 220 113;

6. DE-OS 30 17 274 = U.S. Patent 4,375,202;

7. U.S. Patent 4,309,960;

8. DE-PS 29 31 800 = US-PS 4 335 675.

The following can be seen from Figure 3 of document 1: The blade, which is deformed under the contact pressure, forms the so-called blade working angle at its tip with the web. All stripping devices of the type in question are required that this blade working angle remains unchanged when the contact pressure is varied. This is important for the following reasons:

a) If the blade itself is pressed against the web, then the blade has an obliquely ground blade sweep at its tip. From Figure 6 of document 1 it can be seen that this blade coating surface must always be parallel to the web surface. If the blade is pressed against the running web with only one edge, the quality of the coating suffers.

b) If the blade carries a doctor blade at its tip, it should be noted that the doctor blade rod is known to rest in a doctor bed. There would thus be the danger that the doctor bed would come into contact with the running web if the blade working angle changed as the contact pressure varied.

The various constructions known from the above-mentioned documents all have the common feature that the Squeegee support bar can be pivoted about a first pivot axis which runs transversely to the web running direction as close as possible to the line of attack of the squeegee on the web. This swiveling is necessary in order to be able to vary the basic setting of the doctor blade, for the purpose of adaptation to different types of web, coating compositions or to different doctor blade designs. The blade working angle already mentioned thus arises from this basic setting and from the applied contact pressure.

The above-mentioned requirement to keep the blade working angle unchanged when varying the contact pressure is met in the known constructions with the aid of very different measures and with different success.

In the known device according to documents 1 to 3, the doctor blade support beam - seen in cross section - has an additional pivot axis (D) between the point of application of the doctor blade on the running web and the point of application of the support strip on the blade. (The support bar is arranged there on an extension of the blade clamping device). If the squeegee support beam is pivoted about this additional pivot axis, the contact pressure changes (deforming the blade), with the blade working angle being constant. However, this beneficial effect exists - when working alone with the blade, ie without a doctor blade - only as long as the blade is not or only slightly worn. Blade wear is inevitable with all blade scrapers; The life span of a blade is generally between 1 hour and 10 hours. The device known from documents 1 to 3 thus has the disadvantage that after a certain wear of the blade, keeping the blade working angle constant when varying the contact pressure no longer succeeds to the desired extent. You are thus forced to replace the worn blade with a new blade earlier than would be necessary. Another disadvantage of this known device consists in the following: If the blade is already to a certain extent Degree is worn, then - to increase the contact pressure by a certain amount - the doctor blade beam must be pivoted through a larger angle (about the additional pivot axis D mentioned) than with a new blade. In other words: the adjustment range of the contact pressure is too small in the case mentioned.

The structural design of the known device can be seen from document 2: the doctor blade support beam is supported at both ends in an eccentric disc. The axis of this bearing is the above-mentioned additional pivot axis (D). Each of the eccentric discs is supported in a support. The axis of this bearing is the first pivot axis mentioned at the outset, which is as close as possible to the line of attack of the doctor blade on the material web.

In another known construction according to documents 4 and 5, the support bar is attached to the doctor blade support bar, while an additional bar is provided as the clamping device for the blade, which bar is arranged displaceably in the blade support bar. The plane of displacement and the plane determined by the unloaded blade form an acute angle. The following can be seen from Figures 8 and 9b on page 273 of publication 4: With such a displacement of the blade clamping device, the advantage is that the contact pressure can be adjusted within a fairly large range. A disadvantage, however, is that the blade working angle does not remain exactly the same. At least with a strong change in the contact pressure, there is also a certain change in the blade working angle.

The latter also applies to the further construction known from document 6; see Figure 1. The blade clamping device is not displaceable there along a plane, but can be pivoted about an additional axis.

In the known construction according to document 7, the support bar (6) is arranged on an additional bar (8), which is pivotally attached to the doctor beam. The contact pressure is varied there by swiveling the support bar and changing the shape of the blade. So that the blade working angle remains the same with such a variation of the contact pressure, the following measures are taken there: The drive for the pivoting device of the doctor blade support beam can be actuated by means of a control device depending on the change in shape of the blade, to such an extent that the blade working angle remains unchanged. This construction can in principle meet the above requirement (keeping the blade working angle constant while varying the contact pressure). It is also sometimes disadvantageous that the subsequent pivoting of the doctor support beam to a change in shape of the blade takes place with a certain delay.

In the finally known construction according to document 8, it is provided to change the blade contact pressure the entire doctor beam (6) together with its support supports (9) on both sides by small amounts relative to the counter roller. Here, the support supports (9) are pivoted about a pivot axis (10) located at a great distance from the blade. A disadvantage of this construction is that the first pivot axis of the doctor blade support beam mentioned at the outset is also adjusted, which should be located as close as possible to the line of attack of the doctor blade on the web. This last-mentioned requirement cannot therefore be met continuously in the construction according to document 5. A device for keeping the blade working angle constant when varying the contact pressure is also missing. (The control device known from document 7 described above could be used for this purpose.)

Explanation of the solution principle according to the invention.

The invention has for its object to a stripping device with the features of the preamble of claim 1 create, which - while maintaining the feature that both the support bar and the blade clamping device are rigidly attached to the doctor beam - allows the most accurate and instantaneous maintenance of the blade working angle while varying the contact pressure, even if the contact pressure in a very large range is varied and even if the blade is already relatively heavily worn. In other words, it is the object of the invention that the following requirements are met simultaneously and jointly:

1. The blade working angle should be kept as constant as possible when varying the contact pressure.

2. When working with the blade alone (without a doctor blade), it should also be possible to operate with a blade that is already very worn; i.e. the blade should be used for as long as possible.

3. The contact pressure should be able to be varied in as large a range as possible, even when the blade is already worn.

4. The simple construction of the known doctor blade with rigidly attached support bar and blade clamping device is to be retained.

Additional claims are discussed below.

The object is achieved by the characterizing features f and g of claim 1.

The adjustability of the squeegee support bar specified in feature f (transverse to the direction of the extension of the blade) makes it possible to vary the contact force of the squeegee against the web. In this respect, there is a similarity to the known construction according to document 8. Deviating from this, however, takes place with the Erfin fertilizing said adjustment of the doctor beam without pivoting the support supports; that is, the position of the first pivot axis of the doctor blade support bar, which coincides with the doctor blade line as precisely as possible, remains stationary.

Another step necessary to achieve the object is the coupling of the swivel drive specified for feature g of claim 1 (for swiveling the doctor support beam about said first swivel axis) and the actuator (for adjusting the doctor support beam mentioned in feature f). This coupling need not necessarily be mechanical (although it is preferred). Rather, an electrical coupling of two separate drive motors is also conceivable. The only thing that is decisive is that when the contact pressure (the doctor blade against the running web) varies, both drives are active together, so that the doctor blade support bar carries out a combined movement (triggered by the two drives).

All that is now necessary is to adapt the speeds of the two individual movements to one another in such a way that a change in the contact pressure by a precisely defined amount is coupled with a pivoting of the doctor blade support beam by a precisely defined angle. In other words, the two individual movements are coordinated with one another in such a way that the blade working angle remains completely unchanged during a change in the contact pressure.

As already mentioned, the first pivot axis of the doctor blade support beam always remains stationary, regardless of the contact pressure that is set. As a result, the advantage of the construction known from documents 1 to 3 is retained that the blade working angle can be changed, if necessary, for each set contact pressure (by pivoting the doctor support beam about the first pivot axis) without the contact force changing. An essential feature of the construction known from documents 1 to 3 is that only one of the two possible pivoting movements of the doctor blade support beam can take place at the same time, namely either about the first pivot axis lying in the doctor blade line of attack, or about the mentioned additional pivot axis D. The movement, which instead is provided according to the invention and is composed of two simultaneous individual movements, now makes it possible to change the speed ratio of the two individual movements, preferably as a function of the degree of wear of the blade (if a roller blade is used). This makes it possible to use the advantage of keeping the blade working angle constant when varying the contact pressure not only in the new but also in the largely worn state of the blade. According to the applicant's knowledge, this extraordinarily favorable property has none of the numerous known constructions.

The invention offers a further advantage compared to αen publications 1 to 3: due to the feature f of claim 1 explained above, the adjustment range of the contact pressure is also quite large when the blade is already largely worn out.

In comparison to the constructions known from documents 4 to 7, the construction method according to the invention has i.a. the advantages that neither the support bar nor the blade clamping device have to be designed to be movable relative to the doctor beam and that the blade working angle can be kept constant (when adjusting the contact pressure) with greater accuracy and without a time delay.

Further embodiments of the previously explained solution principle according to the invention are described below using exemplary embodiments with the aid of the drawings. Brief description of the drawings

Fig. 1 shows a stripping device in an oblique view. Fig. 2a, 2b and 2c show the movement sequence of the doctor blade support bar when adjusting the contact pressure in a schematic side view.

3 shows a drive scheme for the screw jacks. FIG. 4 shows an enlarged detail from FIG. 1. FIG. 5 shows a schematic side view of the device shown in FIG.

4 details shown.

Ways of Carrying Out the Invention

The essential individual parts of a stripping device according to the invention can be seen from FIGS. 1 and 2a. Two support supports 20 are rigidly connected to one another by a connecting tube 21 and are mounted in bearing blocks 22 so as to be pivotable about a pivot axis X. In the operating position, the support supports 20 project approximately vertically upwards. At their upper ends they each have a bearing journal 2 or, more generally speaking, a pivot bearing 2. A doctor blade support 5 is supported therein, in a manner which will be described in detail later.

In FIG. 2a, a small piece of the jacket of a counter-roller is indicated by a line C, which is hatched. This roller is omitted in Fig. 1; it runs in the direction of arrow P (FIG. 2a) and leads diagonally from the bottom upwards a paper web which has been coated on its underside with a coating slip. With the help of a doctor, for example an elastic blade 6, the excess coating slip is stripped off the paper web. Seen in cross section (FIG. 2a), the point of attack of the blade on the paper web is as close as possible to the axis of the pivot bearing 2 (this axis is hereinafter referred to as "first pivot axis A"). So that this pivot axis A is always unchanged in the lateral surface C of the counter-roller, the support supports 20 rest in the operating area Condition of the device on a fixed stop 60 each. For overhaul work, the entire device can be pivoted about the axis X, in the case of Figure 2a to the left. The blade 6 is - seen in the cross section of Figure 2a - directly attached to the doctor beam with its lower end. For this purpose, a tensioning strip 8 can be provided, which is only indicated schematically in FIG. 2a. According to FIG. 2a, a support bar 7 is also attached to the doctor beam 5, which supports the blade 6 in the area between the clamping and the tip engaging the paper web. The usual devices for fine adjustment of the support bar 7, which serve to even out the transverse profile of the coating, are omitted.

Instead of the blade 6, a roller squeegee can be inserted into the device described above in a known manner, with the aid of a blade-like elastic holder, to the free end of which the roller squeegee is attached.

The doctor beam 5 has at both ends a support arm 3, which extends in the region of the first pivot axis A. There, each of the support arms 3 has a pivot bearing or journal 4. Its axis is arranged eccentrically to the first pivot axis A and is referred to below as "second pivot axis Z". With the help of the two bearing pins 4, the doctor beam 5 rests pivotably in a respective support element 11, which is preferably designed as an intermediate lever. Each intermediate lever 11 is in turn mounted in the adjacent support bracket 20 by means of the pivot bearing 2 already mentioned. The free end of each intermediate lever 11 is connected to the doctor beam 5 with the aid of a spindle lifting mechanism 10. The doctor blade support beam itself is supported by a further spindle lifting mechanism 12 in a bearing block 13 which is fastened to the connecting tube 21 mentioned above. The screw jack 12 forms the swivel drive for the doctor beam 5; that is, by actuating the spindle hoist 12, the doctor beam 5 together with the Intermediate levers 11 pivoted about the first pivot axis A (see Figures 2b and 2c). This allows, among other things, the basic setting of the angle between the blade and the paper web. 2a, 2b and 2c, only the center lines of the spindle hoists 10 and 12 are shown.

By adjusting the two screw jacks 10, the two intermediate levers 11 are pivoted about the first pivot axis A without the doctor beam 5. As a result, the position of the second pivot axis Z is adjusted relative to the first pivot axis A (see FIGS. 2a and 2b). Viewed in isolation, this pivoting of the intermediate lever 11 has the result that the doctor blade support beam - viewed in cross section - is moved closer to the counter-roller C together with the blade clamping and together with the support bar 7 or is removed therefrom. As a result, the contact pressure of the blade 6 against the paper web is changed while the blade is deformed.

As will be described in more detail below, according to the invention, the two screw jacks 10, which are always connected in a rotationally fixed manner, can be coupled to the screw jack 12 by means of a clutch 36. As a result, the pivoting movements shown in isolation in FIGS. 2a, 2b and 2c can be superimposed on one another. In other words: in reality the transition from the position according to FIG. 2a to the position according to FIG. 2c takes place immediately and not via the intermediate position, which is shown in FIG. 2b.

In Fig. 2a, the blade 6 is shown in the unloaded, undeformed state. The pressure of the blade against the paper web is approximately zero. At the tip of the blade, the blade has an obliquely ground blade sweeping surface that runs exactly parallel to an imaginary tangent T, which is placed on the lateral surface C of the counter roller in the first pivot axis A. The blade 6 and the tangent T enclose the blade working angle k with one another. (In Fig. 2a it is only coincidental that the blade 6 extends parallel to the support supports 20. Of course, other starting positions are also possible.) If you now want to increase the blade contact pressure while deforming the blade 6, it is important that the blade working angle k remains unchanged. Because the mentioned, obliquely ground blade coating surface should remain parallel to the tangent T. Theoretically, the blade contact force could be increased by actuating the screw jacks 10 alone; see Figure 2b. Then the blade working angle would be reduced by the difference angle d to the value k '. The result would be that the blade 6 only rests against the paper web with one edge of the blade coating surface. This must be avoided for the reasons mentioned at the beginning. Therefore, at the same time as the blade contact force is increased, the doctor bar 5 together with the intermediate levers 11 must be pivoted up by the differential angle d about the first pivot axis A (FIG. 2c). It can be seen that in this way the blade working angle k has returned to the original value which it had in FIG. 2a. As already explained, the individual movements theoretically represented in FIGS. 2a to 2c are actually superimposed on one another. As a result, the blade working angle k remains completely unchanged during the entire duration of the combined movement of the doctor beam 5. It is therefore possible to increase or decrease the blade contact force (to vary the thickness of the remaining coating) during operation of the stripping device without changing the blade working angle k. This can ensure a consistently high quality of the coating.

The following can also be seen from FIG. 2a: the bearing journal 4 of the intermediate lever 11, in which the squeegee support beam 5 hangs, is arranged in such a way that the second pivot axis Z is close to that plane B which is determined by the unloaded blade 6. The pivot axis Z is preferably arranged in the region of the back of the paper web, which abuts the counter roller C. It is best to ensure that the second pivot axis Z - in the unloaded state of the blade 6 - lies between the plane B and the tangent plane T. Then the second pivot axis Z - by actuating the screw jacks 10 - transversely to said plane B. Deviating from the above-described arrangement of the second pivot axis Z, the following is also possible: The second pivot axis Z can also be arranged on the blade 6 in the vicinity of the line of attack of the support strip 7. In this case, the pivoting direction of the intermediate lever 11 must be reversed from the arrangement described above.

Another construction, which differs even more from FIGS. 1 and 2a to 2c, could be designed as follows: Instead of the intermediate lever 11, a disc could be mounted on each support support in the pivot bearing 2, which carries the support arm 3 of the doctor beam 5 in a sliding guide. In this case, the sliding guide should make it possible for the doctor blade support bar 5, in a manner similar to that shown in FIGS. 2a and 2b, to be adjustable again transversely to the plane B mentioned, that is to say transversely to the direction in which the blade 6 extends Drive device are provided, which in turn can be coupled to the swivel drive 12 via a coupling.

From Figure 3, the essential parts of the above-mentioned screw jacks 10 and 12 and the associated drive parts can be seen. The spindle or threaded rod 12 engages in a nut 14. This has two journals 15, with which it rests in a bearing block 13 which is fastened to the connecting tube 21 mentioned above. The spindle 12 is driven by means of an electric motor 30, shaft 31 and bevel gears 33 and 34 (with gear housing 32). The spindle 12 can drive the input shaft 37 of a bevel gear distribution gear 39/41 via a clutch 36. This has a gear housing 38 and two output shafts 40, which extend along the doctor beam 5. At each end of the doctor blade support beam 5, a bevel gear angular gear 46, 47, 48 is arranged, which drives the spindle or threaded rod 10 via a universal joint 49. The latter engages in a fork nut 23 which is articulated to the intermediate lever 11. Bearing blocks 43, 44 are provided on the doctor beam 5. The gear housing 46 is rigidly attached to the bearing block 44. In contrast, the housing 38 of the distribution gear 39/41 is pivotally mounted on the bearing blocks 43. The spindle 12 is supported via the bevel gear 34 and an axial bearing 35 on the gear housing 38 and this via the bearing blocks 43 on the doctor beam 5. Thus, rotating the spindle 12, as already described above, pivots the doctor beam 5 about the axis A result. The spindle 10 is supported on the universal joint 49 and on the thrust bearing 45, also on the gear housing 46 and the bearing block 44 on the doctor beam 5. Thus, rotating the two spindles 10 (only one of these spindles is visible in FIG. 3) causes the intermediate levers 11 to pivot about the axis A. This is triggered, when the clutch 36 is engaged, by rotating the spindle 12.

The essential parts of the hoists shown in Figure 3 are given the same reference numerals in Figure 1, although some non-essential details are shown differently in Figures 1 and 3.

FIG. 4 shows an important further embodiment of the invention, which is not shown in FIGS. 1 to 3, namely the variable articulation of the lifting spindle 10 on the intermediate lever 11. One recognizes again the fork nut 23, in which the lifting spindle or threaded rod 10 engages. At its end remote from the pivot axis A, the intermediate lever 11 has a rectangular recess 51 in the form of a sliding guide, in which a sliding block 50 is slidably arranged. The fork nut 23 is connected in an articulated manner to this sliding block 50 (pivot pin 29). In the intermediate lever 11, a threaded spindle 24 is rotatably mounted, which engages in the sliding block 50 and can be rotated by means of a handwheel 25. With this device, it is possible to change the distance between the first pivot axis A and that of the axis of the pivot pin 29. The operation of this device will now be explained with reference to FIG. 5. The positions 29a and 29b of the pivot pin 29 represent the two positions of the intermediate lever 11 in FIGS. 2a and 2b due to a stroke s of the spindle 10.

This pivoting of the intermediate lever 11 results in an adjustment of the doctor beam 5 transversely to the extent of the blade 6 (seen in cross section) by the adjustment path v. At the same time, as explained above, the doctor blade support bar 5 is pivoted by the difference angle d. The adjustment path v and the difference angle d are coordinated with one another in such a way that (as also stated above) the blade working angle k remains constant during the combined adjustment movement. With such a vote, dimensions a and b on blade 6 are taken into account.

a is the distance from the blade tip to the point of application of the support strip 7 and b is the distance from there to the blade clamping device 8.

The ratio a / b can change due to wear of the blade tip or deliberately by moving the point of application of the support bar 7 e.g. by exchanging one support bar for another.

Such a change in the ratio a / b requires a new adjustment of the size ratio d / v, for example by moving the pivot pin 29 from the position 29a to the position 29a '. If the same stroke s of the spindle 10 now takes place, the pivot pin 29 moves into the position 29b '. As a result, the adjustment path of the doctor blade support bar is increased to the value v '.

This change in the effective length of the intermediate lever 11 has the result that - despite the aforementioned change in the dimensional ratio a / b on the blade 6 - the blade working angle k remains constant when the blade contact force is varied. A further possible application of the device according to FIGS. 4 and 5, in conjunction with FIG. 3, is described below. First of all, it should be mentioned that, as is known, wear of the blade by a certain amount (eg 1 mm) results in a certain reduction in the contact pressure. This results in an undesirable increase in the coating thickness on the paper web. Therefore, similar to the known stripping devices, attempts are made to reverse any reduction in the contact pressure as quickly as possible. For this purpose, the motor 30 is briefly switched on, which drives the spindle 12 and - with the clutch 36 engaged - the two spindles 10 in such a way that the doctor blade support beam is adjusted by an amount corresponding to the wear of the blade 6. For this purpose, a control device can be provided which is connected to a measuring device for the coating thickness and which controls the motor 30 in such a way that the coating thickness remains between the respectively permissible limit values. The control device can switch the motor 30 on and off in certain time states. But it is also possible that the control device constantly controls the speed of the motor when it runs continuously at a very low speed. In any case, the described process of gradually or continuously tracking the doctor beam 5 continues until the blade is completely worn.

According to the invention, one can now accomplish the following in the previously described tracking process: You can use the handwheel 25 to select the effective length of the intermediate lever 11 (ie the distance between the first pivot axis A and the axis of the pivot pin 29) such that the blade working angle k remains as constant as possible during the life of a blade. In other words, the effective length of the intermediate lever 11 is set on the basis of experience in the life of the blade used in each case. Another possibility of keeping the blade contact force constant despite the ongoing wear of the blade is described below: An additional drive motor 30 a is coupled to one of the shafts 40 (as shown in broken lines in FIG. 3). When the clutch 36 is released (spindle 12 is stationary), this motor can drive the two spindles 10 in order to pivot the two intermediate levers 11 about axis A alone. This in turn causes the doctor beam 5 to be tracked without, however, pivoting it about the axis A at the same time. That is, there is a gradual adjustment of the doctor beam, similar to that shown in Figures 2a and 2b. In a rough approximation, this is a parallel displacement of the doctor blade support bar 5 in the direction of the counter roller C. However, as is shown in FIGS. 2a and 2b, the blade contact pressure is not increased. Rather, the purpose of this shifting is now to keep the blade contact force constant, taking into account the current blade wear. The advantage of this type of tracking the doctor blade support beam is that the blade working angle k does not change. This means that there are no special measures to keep the blade working angle constant. In particular, the adjustability of the effective length of the intermediate lever 11 shown in FIGS. 4 and 5 is not required.

The possibility of driving the spindles 10 alone can also be used for a completely different purpose: this allows the doctor beam 5 to be moved so close to the counter-roller C that the blade working angle becomes almost zero; ie the working angle of the blade is still considerably smaller than the angle k 'shown in FIG. 2b. The operation of the stripping device in this state is the so-called curved driving style, also known as the “bent blade” driving style; see publication 7, FIG. 4. The construction according to the invention allows the blade contact pressure to be set very sensitively, and at the same time the very, in the “bent blade” mode of operation to keep the small blade working angle precisely constant. The method described above with reference to FIGS. 2a to 2c is used for this. But you can also vary the blade contact pressure by simply turning the spindles 10 (with the clutch 36 released), especially if the blade working angle is set to zero. The above-mentioned additional drive motor 30a is generally not required for the "bent blade" mode of operation. Instead, a handwheel is sufficient.

Claims

1. Device for wiping off excess coating slip from a running web coated with the coating slip, e.g. Paper web, with the following features: a) a doctor blade, which extends transversely to the running direction of the web and which has an elastic blade (6), is held in a blade clamping device (5, 8), which is also transverse to one Squeegee support beam (5) extending in the web running direction is fastened; b) on the doctor beam (5) a support bar (7) is attached, which also extends transversely to the web running direction and with the help of which the free end of the doctor (deforming the blade 6) can be pressed against the web; c) the doctor support beam (5) is supported at both ends in a support element (11); d) each of the support elements is in turn supported in a support bracket (20) by means of a pivot bearing (2), the axis ("first pivot axis" A) of which runs transversely to the web running direction along the line of application of the doctor blade on the web; e) on the doctor support beam (5), a swivel drive (12) engages, which can trigger the joint swiveling of the doctor support beam and the support elements (11) relative to the support supports (20) about said first pivot axis (A);

characterized by the following additional features: f) the squeegee support bar (5) - seen in cross section - is adjustable by means of an actuator (10) relative to the first pivot axis (A), specifically in the sense of positioning the squeegee (6) on the web or back, ie transversely to the direction the extension of the blade (6); g) said swivel drive (12) and said actuator (10) can be coupled to one another.

2. Device according to claim 1, characterized by the following features:

a) each of said support elements (11) is designed as an intermediate lever; b) one end of the intermediate heel (11) is mounted in the support (20) by means of the said pivot bearing (2) (first pivot axis A) and supports the doctor beam (5) with the aid of an additional pivot bearing (4), the axis (second Pivot axis Z) is arranged eccentrically to the first pivot axis (A); c) said actuator (10) is designed as a lifting mechanism (e.g. spindle lifting mechanism) which connects the end of the intermediate lever (11) remote from the pivot axis (A) to the doctor blade support beam.

3. Apparatus according to claim 2, characterized in that said additional pivot bearing (4) - seen in a cross section through the doctor beam (5) - in which the doctor (6) is arranged in the opposite region of the web, approximately in the region of a plane (B) determined by the unloaded blade (6).

4. Apparatus according to claim 2 or 3, characterized in that the distance between the first pivot axis (A) and the point of engagement (29) of said hoist (10) on the intermediate lever (11) is variable (Fig. 4 and 5).

5. Device according to one of claims 1 to 4, characterized in that said actuator (10) is coupled to said swivel drive (12) by means of a clutch (36) (Fig. 3).

6. Device according to one of claims 1 to 5, characterized in that only a single drive motor (30) is provided for the swivel drive (12) and for the actuator (10), which is directly coupled to the swivel drive (12) in a known manner is.

7. Device according to one of claims 1 to 5, characterized in that a separate drive motor is provided for the swivel drive (12) and for the actuator (10).

8. Device according to one of claims 5 to 7, characterized by the following features: a) the swivel drive has a threaded spindle (12) arranged in the central region of the doctor support beam (5) and drivable by a motor (30); b) the threaded spindle (12) engages in a nut (14) which is pivotably mounted on the support supports (20) and is mounted by means of an axial bearing (35) on a gear housing (36) which in turn is pivotably mounted on the doctor beam (5); c) the gear housing (38) contains said clutch (36) and gear elements (39, 41) which establish a drive connection from the clutch to said actuator (10).

9. Device according to one of claims 2 to 8, characterized by the following features: a) the Spindelhuowerk of the actuator (10) comprises a threaded spindle (10) which engages in a nut (23) pivotally mounted on the intermediate lever (11); b) the threaded spindle (10) is supported via an articulated coupling (49) and an axial bearing (45) on the doctor beam (5).

10. The device according to claim 9, characterized in that the threaded spindle (10) on a on the doctor blade beam (5) rigidly fixed gear housing (46) is supported, the drive elements (47, 48) for the threaded spindle (10).