EP0882839B1 - Apparatus for the application of a liquid or pasty fluid to a moving web - Google Patents

Description

The invention relates to a device for applying a liquid or pasty application medium on a moving surface according to the preamble of claim 1.

A generic application device is known from EP 0 289 824 A2 known. The application device shown in this document has one by means of appropriate storage chamber delimitation elements on the underground inlet side or storage space limited on the underground outlet side and one in the direction of travel of the subsoil in front of the storage chamber inlet limiting element arranged feed device for feeding application medium on. The storage chamber delimitation elements are fixed to the doctor bar connected. In an embodiment shown there, the storage chamber entry delimitation element is orthogonal to the coated surface of the running surface adjustable on the squeegee, so that a Adjustment of the height of the limiting element between the subsurface and the storage chamber entrance formed gap is possible. Furthermore, in the storage chamber application medium outlet channels with variable cross-section provided to the application medium pressure inside the storage chamber to decrease and so against the direction of underground movement directional flow of application medium through the storage chamber egress step to avoid through. A disadvantage of this application device is that, on the one hand, the doctor bar is only relatively large Effort changed in terms of its location with regard to the current subsurface on the other hand by changing the gap height and the cross-sectional area of the application medium outlet channels alone for the selected substrate, the medium to be applied and the desired underground speed optimal operating condition is easily adjustable.

An application device, the application medium feed device in the running direction of the subsoil in front of the storage chamber inlet limiting element is also known from US 4,963,397 A. At this The elements delimiting the storage chamber are rigid with the device Squeegee beam connected, so that a change in position of the squeegee beam Optimization of the storage chamber shape suitable for the respective surface and size is associated with considerable effort.

An application device with an underground inlet side by a Gap and chamber on the outlet outlet side delimited by a doctor blade is known from US 4,859,507 A. The chamber shown there is not completely filled with order medium during order operation. Rather, it is designed so that when the order is addressed to the Chamber walls against the direction of travel of the substrate to the chamber entrance bordering gap forms flowing application medium film. The application medium film occurs at the chamber entry gap against that of the application medium carried into the chamber and flowing into the chamber and leads to additional moistening of the surface and to smooth the damp application layer on the surface. Also this chamber is rigidly connected to the squeegee beam, so here too the above disadvantages occur.

An application device is known from EP 0 319 503 B1, in which the application medium supply mainly between the storage chamber delimiting elements takes place, and in which in the one Doctor blade formed baffle entry restriction passages are provided, through which in excess introduced into the storage chamber Application medium against the direction of the substrate from the Stowage chamber can escape or in which in the direction of travel of the ground an additional one in front of the storage chamber inlet limiting element Order medium supply is provided. Even with this application device is the doctor blade with the storage chamber rigidly connected to it in its position with respect to the subsurface only with a relatively large Effort changeable.

From the publications DE 42 03 389 A1 and US 4 245 582 A it is known the position or the contact pressure of a doctor element, such as. B. a squeegee blade or a squeegee, by means of adjusting devices.

In contrast, it is an object of the present invention, a generic Device for applying a liquid or pasty application medium to indicate on a moving surface whose Storage chamber compared to the prior art with less effort with regard to a desired application medium, a desired one Underground and a desired underground speed optimal is adjustable.

This task is performed by a generic application device solved the features of the characterizing part of claim 1. According to the invention can be changed using an adjusting device of the storage chamber outlet limiting element against the underground First, the desired size of the order gap is specified. With the help of an adjusting device for changing the position of the storage chamber inlet limiting element then against the underground Size of the entry opening into the storage chamber or / and the size and Shape of the storage chamber can be influenced. Any of the above Adjustment devices can be a plurality of across the width of the substrate distributed control units, which are independent are operable from each other, so that there is a profiling of the storage chamber inlet opening or / and profiling the size and shape of the Storage chamber across the width of the applicator, i.e. in the transverse direction, can be achieved.

Furthermore, the application device according to the invention is based on the arrangement of the feed device in front of the storage chamber inlet limiting element the order medium across the entire order range on the Boundary chamber outlet limiting element, for example a doctor element, with essentially the same pressure so that the latter in is "flushed" to a high degree evenly and ultimately becomes even Layer application can be achieved on the substrate. As a result of the pressure equalization effect the arrangement is sufficient for a smaller pre-metering amount to achieve the desired layer order. Moreover can be due to the possibility of using a smaller excess of application medium to work, the acquisition and operating costs of the invention Keep application device low. The for the revolution of the Excess pump medium required pump capacity namely be kept correspondingly small.

This is the case in order to achieve a desired job cross-section the squeegee forming pressure cross profile is important. To set one desired pressure cross profile you can in the volume of the storage chamber Profiling the cross direction or the shape with a constant storage chamber volume of the baffle cross section in the transverse direction or the passage cross sections a plurality provided in the transverse direction next to each other Specify return flow passages independently of each other.

The above-described effect of the application device according to the invention can be further improved by the fact that the storage chamber entry limiting element or / and an underground inlet side and Storage chamber wall connecting the outlet outlet side of the storage chamber with regard to an equalization of the application medium is formed in the transverse direction. This can be provided, for example be that the storage chamber a smoothing section and has a subsequent order section. The order section the storage chamber ensures that, if necessary, in the Storage chamber still existing pressure differences, for example due to of eddies or the like, not going into the immediate Can spread near the squeegee.

In the area of the storage chamber entrance, the compensation can be done in the transverse direction are supported, for example, by the fact that the storage chamber entry limiting element seen uneven in the direction of the underground, for example corrugated, stepped or with a predetermined roughness, is formed, preferably in the area of its closest approximation to the underground. In this case you make one of these Use unevenness caused diffuser effect. This diffuser effect can also by appropriate design of the storage chamber wall be used in the area of the storage chamber. In addition to the above mentioned possibilities of wavy, graded or rough training the storage chamber wall also comes from the installation or attachment of Web, rods or the like into the storage chamber into consideration.

It is true that if you work with an excess of application medium, basically conceivable that in the area of the storage chamber entrance Form flow conditions at which the application medium in an underground flow in the direction of the flow into the Storage chamber enters and in a distance away from the ground, against the direction of travel directed excess flow the excess application medium emerges from the storage chamber again. At least one is preferred a return flow passage already mentioned above provide through which excess that has entered the storage chamber Order medium can emerge from this again. The advantage of such Backflow passages can be seen in the fact that they are in the range of stowage chamber inlet formed by the stowage chamber inlet limiting element lead to defined flow conditions. These backflow passages can for example separate the doctor bed penetrating Lines or channels. Furthermore, the backflow passages optionally and preferably can be opened or closed independently of one another his.

The storage chamber inlet limiting element can be, for example, a a holder of the storage chamber outlet limiting element in one piece be a trained element. However, it is also possible that the storage chamber entry limiting element one from the holder of the storage chamber outlet limiting element separately formed element. The first-mentioned embodiment is characterized by simple and robust construction, whereas the latter variant offers the possibility of depending on the stowage chamber entry limiting element the properties of the respective application medium and others Operating parameters of the application device, in particular the running speed of the underground to choose. As separately trained Damage chamber inlet limiting elements come in particular doctor blades in question, both in terms of training as a drag blade as well can be thought of as a stabbing blade. Because pricking blades due to the fact that they are directed against the direction of travel of the subsurface are pressed against the surface by the incoming application medium they should preferably be near the surface have at least one entry passage. In both cases in addition, the return flow passages mentioned above in formed simply by holes provided in the blade elements his.

Regardless of the one, one-piece or separate mentioned above Formation of the storage chamber inlet limiting element can this is a training area for the from the feeder to the Application medium applied underground and entering the storage chamber exhibit. Through this instruction or funnel surface, the desired pressure equalization in the transverse direction improved and the proper Entry of the application medium into the storage chamber ensured become.

A particularly advantageous influencing of the flow dynamics in the Storage medium entering or entering the application medium can, for example be obtained in that the from the instruction surface or / and the stowage chamber wall with the cavity-limited cavity has a venturi tube-like cross section.

An edge of the storage chamber inlet limiting element adjacent to the ground can be seen in the transverse direction, for example, rectilinear run. However, this edge has protruding towards the surface Sections and sections recessed in relation to the subsurface or has an edge of the storage chamber inlet limiting element which is adjacent to the subsurface at least one entry passage on, a desired minimum inlet cross-section for Application medium can be guaranteed in the storage chamber. Furthermore is by the latter training also a targeted non-uniformity of the application medium possible in the transverse direction, with the corresponding resultant Uneven line application. For example, the edge wavy, sawtooth, step-like or the like.

The storage chamber inlet limiting element can be attached to the bracket Damage chamber outlet limiting element be firmly connected. It is however, it is also possible to place the stowage chamber inlet limiting element on the Holding of the storage chamber outlet limiting element relative to this to be arranged displaceably or the stowage chamber entry element with the holder of the storage chamber outlet limiting element via a To connect the web section, the limited tilting movement of the storage chamber inlet limiting element allows relative to the bracket. All these design variants allow the stowage chamber to be influenced in a targeted manner regardless of the respective position of the storage chamber outlet limiting element against the underground. In the case of the first variant this influence can be changed, for example the relative orientation of the bracket and the surface. In case of second- and third-mentioned design variants can additionally one Relative movement of the storage chamber entry limiting element relative to the bracket used for this influencing the storage chamber become.

The actuating units can be electrical and / or hydraulic or / and pneumatic or / and be hydropneumatic or / and manually operable. For example, at least some of the adjusting units can be set screws be educated. Additionally or alternatively, at least part of the Adjustment units of pressure hose units can be formed. It is also possible that the actuator divided into a plurality of chambers Pressure hose includes. Remote actuators or remote actuators Actuators can easily be in the stroke order control loop be involved. In addition, the positioning force or The control intensity of the control device (s) and / or control unit (s) can be controlled or be adjustable.

As can be seen from the discussion above, it works through cooperation of the storage chamber inlet limiting element and the subsurface formed entry opening into the storage chamber on the application medium certain throttling effect. This throttling effect has a pre-metering of the order medium. An even finer pre-dosing can can be achieved, for example, in that the feed device a A plurality of feed elements arranged distributed over the width of the substrate having. The application medium application rate is preferably of these feed elements independently adjustable, which in particular with a view to achieving a transversely changing Stroke profile is an advantage.

Figur 1

eine schematische, teilweise im Schnitt gehaltene Seitenansicht einer erfindungsgemäßen Auftragsvorrichtung;

Figur 2

eine schematische Seitenansicht der wesentlichen Elemente einer zweiten Ausführungsform;

Figuren 3 bis 9

Ansichten analog Figur 2 weiterer Ausführungsformen; und

Figuren 10a bis 10c

Schnittansichten längs der Linie XI-XI in Figur 2 dreier Kantengestaltungen zwischen Staukammereintritt-Begrenzungselement und Untergrund.

The invention will be explained in more detail in the following using some exemplary embodiments with reference to the accompanying drawings. It shows:

Figure 1

is a schematic, partly in section side view of an application device according to the invention;

Figure 2

is a schematic side view of the essential elements of a second embodiment;

Figures 3 to 9

Views analogous to FIG. 2 of further embodiments; and

Figures 10a to 10c

Sectional views along the line XI-XI in Figure 2 of three edge configurations between the stowage chamber entry limiting element and the ground.

In Figure 1, an application device according to the invention is generally 10 designated. It is used to apply a uniform layer S one liquid or pasty application medium M on one on the application device 10 moving underground U. The underground U can for example be formed by an application roller; the layer S but can also directly on a moving past the applicator Material web made of paper, cardboard or cardboard can be applied.

In the illustrated embodiment, the application device comprises 10 a doctor blade device 12 with a roller doctor blade 14, a storage chamber 16 and a feed device 18, by means of which the application medium M is rough distributed on the underground U is applied. The doctor blade 14 is in a doctor bed 20, which has a conventional structure and therefore will not be described in more detail below. The underground U moves on the application device 10 in the direction of the arrow L (running direction) over. The storage chamber 16 is on the outlet side of the Squeegee element 14 limits that as a storage chamber outlet limiting element is used, and on the inlet side of a storage chamber inlet limiting element 22 completed. In addition, the storage chamber 16 from the underground U and one of the storage chamber inlet limiting element 22 and Doctor blade 14 connecting stowage chamber wall 24 limited.

The application medium M is through the feed device 18 in the running direction L applied to the underground U in front of the storage chamber entry 26, albeit with a rather uneven layer structure, as in FIG. 1 indicated by the irregular arrangement of the large number of black dots is. When moving with the underground U, the application medium arrives M in the area of the entry gap 26 in front of it consequently throttling action accumulates. This collection 28 of order medium M seals the storage chamber 16 on the inlet side against the unwanted Entry of air from. As a result of the hydrodynamic inflow pressure of the application medium M in front of the entry gap 26 is widened and enables application medium M into the storage chamber 16 arrives. Finally, the application medium passes through the underground U and squeegee 14 existing exit gap 30 again from the Storage chamber 16 from, due to the effect of the invention Application device 10, in particular the stowage chamber entry limiting element 22, the storage chamber 16 and the doctor device 12 as uniform layer application S on the underground U.

The uniformity of the layer S applied with the device 10 is based primarily on the fact that the pending on the doctor blade 14 Application medium M an even distribution and an even Transverse pressure profile, i.e. in a to the plane of Figure 1 in essentially orthogonal direction. This even Profile is based, on the one hand, on the throttling action of the storage chamber inlet limiting element 22, as a result of which it is already in the order medium accumulation 28 there is a compensation in the transverse direction Q, and on the other hand on the effect of the storage chamber 16, which leads to a further compensation in the transverse direction Q leads.

The cross-compensation in the order medium M can by the design the stowage chamber wall 24, the stowage chamber inlet limiting element 22, in particular the entry gap 26, are influenced, and through the design of a directing surface 32, which extends from the stowage chamber entry limiting element 22 starting against the direction of travel L of the underground U extends. Particularly favorable hydrodynamic Conditions in the order medium jam 28 can then, for example can be achieved when the underground U and the guide surface 32 a in have essential Venturi tube-like cross-section.

In the exemplary embodiment shown in FIG. 1, the stowage chamber entry limiting element is 22 integrally formed with the doctor bed 20. The doctor bed 20 is attached to the doctor bar 36 via a leaf spring 34, in particular by means of an actuating device 38 on this doctor bar 36 clamped. The adjusting device 38 is shown in FIG Double arrow only roughly indicated and can for example be formed by a pressure hose.

By the width of the exit or order gap 30 depending on Operating parameters such as viscosity of the application medium M, running speed of the underground U and the like to achieve the desired To be able to set the layer thickness is also one Actuating device 40 for influencing the setting of the doctor element 14 against the underground U provided. Finally, in the embodiment 1 also affects the width of the entry gap 26 be, by means of an actuator 42. As actuators 40 and 42 any suitable actuating devices can be used, for example, manually operated set screws, electromotive Actuable actuators or also hydraulically, pneumatically or hydropneumatically actuatable actuating units, such as pressure hoses. In order to influence the layer application more precisely and if necessary to be able to achieve a desired profiling of the layer application the actuators 40 or / and 42 in the transverse direction Q in a plurality Control sections divided, both independently and in their actuating force or actuating intensity are adjustable or controllable. This is indicated in Figure 12a by the actuators 42a, 42b and 42c. It is when using remotely operated actuators or units in addition, this is possible in the control loop of the entire order facility 10 to include.

Although in Figure 1 and also in the other embodiments according to Figures 2 to 10 always shown doctor devices with a doctor blade 14 in connection with the present invention other doctor or leveling elements can also be used, for example Doctor blades, air brushes or the like. Also are the design there are no limits to the surface of the squeegee. Furthermore it is understood that the doctor blade 14, as is customary in the prior art, driven in the same or opposite direction to the running movement of the underground U. can be.

It should also be noted that any type of feed device is used can be. With regard to the profiling mentioned above of the line application, however, it is advantageous if also the feed device 18 in a plurality arranged side by side in the transverse direction Q. Feed sections is divided, which the application medium M with the desired line profile corresponding to different feed rates apply the underground U. For this purpose, the feed device 18 can, for example a plurality of arranged over the width of the order Include application nozzles, the throughput of application medium preferably can be set separately for each of these application nozzles.

The one applied to the substrate U by the feed device 18 The amount of application medium M can correspond to the desired layer application S. applied precisely dosed. However, it is also possible apply the application medium M to the underground U in excess. In this case, however, it is then advantageous to use the storage chamber 16 outgoing return flow passages 44 (shown in dashed lines in FIG. 1) provide through which excess introduced into the storage chamber 16 Application medium M can emerge from the storage chamber again. The The passage cross section of the return flow passages 44 can be, for example, by means of Valves 44a to any desired value, including complete Opening and closing completely. The Excess application medium emerging from the return flow passages 44 M can be collected by means of a sump 46 and the Order process are fed again.

As already mentioned above, the equalization of the Order medium or the pressure prevailing in it through the design the storage chamber 16, in particular the storage chamber wall 24 thereof by influencing the position of the storage chamber inlet limiting element 22 against the underground U depending on operating parameters such as viscosity of the application medium M, running speed of the underground U and the like can be influenced. Regarding Figures 2 to 10 are therefore different design options of the storage chamber and the storage chamber wall are discussed.

In the embodiment according to FIG. 2, the storage chamber 116 has one equalization section 116a adjacent to entry gap 126 and an order portion 116b adjacent the exit gap 130 on. In the equalization section 116a, the pressure of the through the entry gap 126 inflowing application medium to the in the pressure prevailing in the stowage chamber 116. In addition, it comes to Uniformization of the pressure profile in the transverse direction Q. In the order section 116b, the application medium M then already has a uniform one Pressure profile on, so that the doctor element 114 correspondingly even "rinsed", and ultimately the desired uniform Layer order results. In addition, an adjusting device 141 is provided for example an expandable pressure hose, by means of which the Shape of the storage chamber 116, for example that orthogonal to the transverse direction Q taken cross section of the storage chamber 116, can be changed.

In the embodiment according to FIG. 3, the storage chamber 216 has a the baffle entry restriction member 222 with respect to the direction of travel L of the subsurface U undercut section 216c. On such undercut portion 216c is particularly with respect to an always complete filling of the storage chamber 216 favorable.

In the embodiment according to FIG. 4, the storage chamber 316 is on the one hand through the doctor bed 320 and on the other hand through one on the doctor bed 320 fixed blade 346 limited. The free end of this blade 346 forms in in this embodiment, the jam entry restriction member 322. The above-mentioned free end of the blade 346 points in the running direction L, the blade 346 is thus designed as a drag blade. The backflow passages 344 in the embodiment according to FIG holes formed in the blade 346.

The storage chamber 416 is also in the embodiment according to FIG. 5 partially delimited by a blade 446 attached to the doctor bed 420. in the Differing from the blade 346 is the blade 446 of the embodiment according to FIG. 5, however, designed as a piercing blade, i.e. as one against the direction L of the substrate U directed blade. Because such Pricking blade due to the hydrodynamic pressure of the application medium supplied to it is pressed against the surface of the underground U, has the piercing blade 446 openings, which the function of Take entry gap 426.

A piercing blade 546 is also used in the embodiment according to FIG. 6 intended. In contrast to the embodiment according to FIG Prick blade 546, however, has an instruction surface at its free end 532 for incoming application medium M, so that it as a result the hydrodynamic inflow pressure of the application medium with release of an entrance slit 526 lifts from underground U.

In a further embodiment not shown in the figures the storage chamber inlet limiting element delimiting the storage chamber on the inlet side in the area of the entrance slit in the direction of the Be designed underground. The one of this design of the storage chamber entry limiting element induced step diffuser effect improves the uniformity of the prevailing in the application medium Transverse pressure. The mentioned diffuser effect can also with others specifically targeted uneven in the running direction of the subsurface Formations of the storage chamber inlet limiting element can be obtained.

Furthermore, the entire storage chamber wall of the storage chamber in Direction of travel of the subsurface may be stepped.

In the above-described embodiments according to FIGS. 1 to 6, the size of the storage chamber 16, 116, ..., 516 or the size of the Entry gap 26, 126, ..., 526 with the same size of the exit gap 30, 130, ..., 530 only by changing the relative orientation of the Doctor bed 20, 120, ..., 520 with respect to the underground U are changed. With reference to Figures 7 and 8 are two embodiments in the following are presented, in which the stowage chamber restriction element is displaceable relative to the doctor bed.

In the embodiment according to FIG. 7, the storage chamber entry limiting element 822 on the doctor bed 820 in the direction of the double arrow V linear slidably attached, for example by means of a dovetail guide or similar. With a linear adjustment of the storage chamber inlet limiting element 822 remains the size of the storage chamber 816 in essentially unchanged, only the size of the entry gap 826 increases according to this adjustment to or from.

In the embodiment according to FIG. 8, the storage chamber entry limiting element 922 formed in one piece with the doctor bed 920. It is with this however only over a relatively weakly dimensioned Bridge 950 connected. The elasticity of the web 950 leaves a limited Tilting of the storage chamber entry limiting element 922 by one in Transverse direction Q, axis A essentially extending through the web 950 to. In one caused by the actuation of the actuating device 942 Tilt change both the size of the storage chamber 916 and the width of the entry gap 926. Of course, it is in a modification the embodiment according to FIG. 8 also possible, doctor bed and stowage chamber entrance limiting element as separate from each other Form elements that can be tilted together about the axis A. are.

Although in the exemplary embodiments explained above according to figures 1 to 8 the storage chamber outlet limiting element always from one Doctor element is formed, the invention is not limited to this. As in Figure 9 is shown, the metering chamber 1016 on one of the Doctor device 1012 separately formed and arranged separately Bracket 1060 may be provided. Both the stowage chamber entry limiting element 1022 as well as the storage chamber outlet limiting element 1062 with the mounting part 1060 also in one piece be formed, as shown in Figure 9, in which case the element 1060 does not take on the mounting function in the actual sense. With regard to the possibilities of forming the mounting part 1060 is based on the possibilities of training described above Doctor device and in particular the doctor bed.

In Figure 10 are three variants of the design of the underground and stowage chamber entrance restriction element existing entrance gap shown. In the variant shown in FIG. 10a, both the Underground U 'as well as the storage chamber entry limiting element 22' over straight lines running in the transverse direction Q K1 'and K2'. In the extreme case, the entry gap 26 'can thus be complete getting closed. In contrast, in the variant according to FIG. 10b the Edge K1 "of the storage chamber entry limiting element 22" is stepped with sections 22 "a projecting towards the underground U" and with respect of the subsurface U "recessed portions 22" b while the edge K2 "of the underground U" runs in a straight line. When the projecting Sections 22 "a on the underground U" thus have a minimal entry opening 26 "between underground U" and stowage chamber entry element 22 ". According to FIG. 10c, a minimal entry opening 26" 'can also be used with the help of the openings provided in the area of the edge K1 "' 22 "'c of the storage chamber inlet limiting element 22"' can be achieved.

Although a step-shaped course of the edge line K1 "is shown in FIG. 10b it is understood that any edge course is provided can be, which ensures a minimal cross section of the inlet opening. For example, the edge K1 "could also be wave-shaped, sawtooth-shaped or the like.

It should be noted that the numerous design options of the application device 10 according to the invention described above can also be combined with one another to form embodiments which have not been explicitly described above as embodiment variants of the invention. It is thus possible, for example, to provide the edge variants according to FIG. 10 with drag or piercing blades, as have been described with reference to FIGS. 4, 5 and 6. It is also possible with the blade variants according to FIGS. 4, 5 and 6 to provide return flow passages which do not run through the blade body but through the doctor bed. Furthermore, the blades acting as a storage chamber entry delimiting element can be arranged on the doctor bed in a linearly displaceable or pivotable manner based on the embodiments according to FIGS. 7 and 8. In addition, it is also possible, in the embodiments according to FIGS. 3 to 8, to design the stowage chamber in accordance with the embodiment according to FIG. 2 with a pressure build-up and equalization section and an application section.
The application device according to the invention can also advantageously be used in the applicant's so-called "speedsizer", ie a system which works with application rollers for coating a material web on both sides.

Claims (27)

1. Apparatus (10) for applying a liquid or pasty application medium (M) to a base (U) moving past, for example a web of paper, board or paperboard or an applicator roll, comprising:

   a pond chamber (16) which is arranged on a doctor bar (36) and is bounded on the base inlet side by a pond chamber inlet boundary element (22) and on the base outlet side by a pond chamber outlet boundary element (12), the pond chamber inlet boundary element (22) together with the base (U) forming an inlet gap (26), acting as a restrictor with respect to the application medium, to seal off the pond chamber (16) on the inlet side against the entry of air, and

   a feed device (18) for feeding the application medium (M), the feed device (18) being arranged upstream of the pond chamber inlet boundary element (22), as viewed in the running direction (L) of the base (U),

   characterized in that it further comprises actuating devices (40, 42) by means of which the pond chamber (16) on the doctor bar (36) is arranged to be adjustable relative to the latter, the actuating devices (40, 42) being provided to change the setting of the pond chamber outlet boundary element (12) and of the pond chamber inlet boundary element (22) against the base (U) in such a way that they can be used to vary the size of the application gap (30) and of the inlet gap (26) and the volume and/or the shape of the pond chamber (16).
2. Applicator according to Claim 1, characterized in that the pond chamber inlet boundary element (22) and/or a pond chamber wall (24) connecting the base inlet side and base outlet side of the pond chamber (16) to each other is designed with a view to evening the application medium (M) in the transverse direction (Q).
3. Applicator according to Claim 2, characterized in that the pond chamber (116) has an evening section (116a) and an adjacent application section (116b).
4. Applicator according to Claim 2 or 3, characterized in that the pond chamber inlet boundary element, as viewed in the running direction (L) of the base (U), is designed to be uneven, for example corrugated, stepped or with a predetermined roughness, to be specific preferably in the area of its closest approach to the base (U).
5. Applicator according to one of Claims 2 to 4, characterized in that the pond chamber wall, as viewed in the running direction (L) of the base (U), is designed to be uneven, for example corrugated, stepped or with a predetermined roughness, or in that built-in or built-on fittings, such as webs or rods, are provided in the pond chamber.
6. Applicator according to one of Claims 1 to 5, characterized in that at least one return passage (44) is provided, through which excess application medium (M) which has entered the pond chamber (16) can emerge from the latter again.
7. Applicator according to Claim 6, characterized in that the passage cross section of at least one return passage (44) can be varied as desired.
8. Applicator according to one of Claims 1 to 7, characterized in that the pond chamber inlet boundary element (22) is an element formed in one piece with a holder (20) of the pond chamber outlet boundary element (12).
9. Applicator according to one of Claims 1 to 7, characterized in that the pond chamber inlet boundary element (322; 422; 522; 822) is an element formed separately from a holder (320; 420; 520; 820) of the pond chamber outlet boundary element.
10. Applicator according to Claim 9, characterized in that the pond chamber inlet boundary element (322) comprises a trailing blade (346).
11. Applicator according to Claim 9, characterized in that the pond chamber inlet boundary element (422; 522) comprises a leading blade (446; 546) preferably formed with at least one inlet passage.
12. Applicator according to one of Claims 1 to 11, characterized in that the pond chamber inlet boundary element (22; 522) has an admission face (32; 532) for the application medium (M) applied to the base (U) from the feed device (18) and entering the pond chamber (16; 516).
13. Applicator according to Claim 12, characterized in that the hollow space bounded by the admission face (32) and/or the pond chamber wall (24) with the base (U) has a cross section formed in the manner or a venturi tube.
14. Applicator according to one of Claims 1 to 13, characterized in that an edge (K1') of the pond chamber inlet boundary element (22') adjacent to the base (U') runs rectilinearly, as viewed in the transverse direction (Q).
15. Applicator according to one of Claims 1 to 13, characterized in that an edge (K1'') of the pond chamber inlet boundary element (22'') adjacent to the base (U'') has sections (22''a, 22''b) which project and are set back with respect to the base (U'').
16. Applicator according to one of Claims 1 to 13, characterized in that an edge (K1''') of the pond chamber inlet boundary element (22''') adjacent to the base (U''') has at least one inlet passage (22'''c).
17. Applicator according to one of Claims 1 to 16, characterized in that the pond chamber inlet boundary element (22; 122; 222; 322; 422; 522; 1022) is firmly connected to a holder (20; 120; 220; 320; 420; 520; 1060) of the pond chamber outlet boundary element.
18. Applicator according to one of claims 1 to 16, characterized in that the pond chamber inlet boundary element (822) is arranged on a holder (820) of the pond chamber outlet boundary element such that it can be displaced relative to the latter.
19. Applicator according to one of Claims 1 to 16, characterized in that the pond chamber inlet boundary element (922) is connected to a holder (920) of the pond chamber outlet boundary element via a web section (950), which permits a limited tilting movement of the pond chamber inlet boundary element (922) relative to the holder (920).
20. Applicator according to one of Claims 1 to 19, characterized in that at least one actuating device (42) comprises a plurality of actuating units (42a, 42b, 42c) which are arranged distributed in the transverse direction (Q) and which can be actuated independently of one another.
21. Applicator according to Claim 20, characterized in that the actuating units can be actuated electrically and/or hydraulically and/or pneumatically and/or hydropneumatically and/or by hand.
22. Applicator according to Claim 20 or 21, characterized in that at least some of the actuating units are formed by setting screws.
23. Applicator according to one of Claims 20 to 22, characterized in that at least some of the actuating units are formed by pressure hose units.
24. Applicator according to one of Claims 1 to 23, characterized in that the actuating device comprises a pressure hose subdivided into a plurality of chambers.
25. Applicator according to one of Claims 1 to 24, characterized in that the actuating force or actuating intensity of the actuating device or of the actuating unit can be controlled or regulated.
26. Applicator according to one of Claims 1 to 25, characterized in that the feed device (18) has a plurality of feed elements arranged distributed in the transverse direction (Q).
27. Applicator according to Claim 26, characterized in that the feed elements can be adjusted independently of one another with respect to their throughput of application medium (M).

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