DE19757678A1 - Web coating applicator for paper or cardboard - Google Patents

Abstract

The apparatus (10) for a direct or indirect application of a liquid or paste coating (12), to the surface of a moving web (14), has outlet channels (28) across the direction of the web movement, to deliver the coating (12) to the web (14). The cross-section surface (F) of the distributor channel (22) decreases from at least one feed opening (24) according to the flow characteristics of the coating medium. The reduction in the cross-section surface, at a set gap from the feed opening (24), is increased according to lower viscosity of the coating medium (12), and can decrease increasingly at a steady displacement from the feed opening. The distributor channel (22) can have a constant decrease in the cross-section surface. The dimensions of the outlet channels and the distributor channel are set so that the pressure drop in the outlet channels is greater than in the distributor channel. The sum of the outlet channel cross-section surfaces is smaller than the cross-section surface of the distributor, and preferably less than half the distributor cross-section surface. When using a coating medium with a viscosity of \- 2 Pa\*s (2000 cP), the sum of the outlet channel cross-section surfaces is more than the cross-section surface of the distributor channel. The length of the outlet channels is \- 5 mm and they have a diameter of <= 10 mm. The ends of the outlet channels have a sharp limiting edge. The feed opening (24) is at an end of the length of the distributor pipe (18), with an outlet opening (26) or a further feed opening at the other end. The distributor pipe can have a number of feed openings along its length.

Description

The invention relates to a device for direct or indirect on carrying liquid or pasty application medium on a material web, in particular made of paper or cardboard, with a in the transverse direction of the mate rialbahn extending distribution pipe, the distribution pipe a distribution channel and comprises a rigid pipe wall surrounding the distribution channel, and where with at least one feed opening for application medium in the tube wall and a plurality of distributed in the transverse direction of the web Neten outlet channels are provided for dispensing the application medium.

EP 0 570 733 A1 describes an application device of the generic type known type, whose commissioned work to achieve a possible uniform line application to the material web a distribution pipe and a this has parallel arranged feed pipe, the distribution pipe and the feed pipe over a plurality of in the transverse direction of the material web distributed stub lines are interconnected. In these Stub lines are devices for influencing the material's own properties provided for the application medium. That in the manifold over the The working width of the material spread over the material web is thus reached first in the branch lines, in which its properties with regard to a possible even stroke order can be changed before it is in the feed pipe arrives, through the outlet openings of which it finally is applied to the material web. The Kon described above structure has proven to be too complex and therefore in acquisition and maintenance proven too expensive.  

In contrast, it is an object of the invention, an application device Specify generic type, which with a structurally simple structure Achievement of a uniform stroke order.

According to a first aspect of the invention, this object is achieved with a generic application device solved in that the Exit channels deliver the application medium to the material web and that the cross-sectional area of the distribution channel starting from the at least a feed opening decreases, the cross-sectional area decrease in Dependence on the rheological properties of the application medium is selected.

The "decrease in cross-sectional area" is understood to mean the change in the cross-sectional area of the distribution channel depending on the length unit measured in the transverse direction of the material web. So it has the unit 1 m (= 1 m ² / m). The course of the value of the cross-sectional area as a function of the distance from the at least one feed opening will therefore preferably be chosen according to the invention in such a way that the application medium is present in the distribution pipe at the inlet of each outlet channel with a pressure which corresponds to the throughput desired for the respective outlet channel (= quantity of order medium delivered per unit of time). In the case of outlet channels which are identical to one another and are arranged at constant intervals, the pressure present at these outlet channels should therefore have the same value in each case. It is thus ensured that when setting the desired operating parameters of the application device, this applies the desired amount of application medium to the material web with the desired uniformity. According to the above, it is possible to work with a custom-built and thus inexpensive order work and maintenance without having to accept losses in uniformity. The application device according to the invention also has the further advantage that the desired material properties of the application medium, which are preset in a preparation container, do not have to be subsequently changed again in the application unit.

In order for the distribution tube, in particular the outlet channels with lower viscosity of the application medium associated higher throughputs through the outlet channels term, it is proposed that the cross-sectional area decrease the larger ge at a predetermined distance from the feed opening is selected, the lower the value of the viscosity of the application medium. Of the predetermined distance can be anywhere on the distribution pipe be chosen.

Depending on the rheological properties of the application medium and the desired throughput through the outlet channels be advantageous if the decrease in the cross-sectional areas of the distribution channel increases with increasing distance from the feed opening or decreases or remains constant. An increasing cross-sectional area decrease will be, for example, with low-viscosity application media in To consider. On the other hand, when using high viscosity Order media rather for a decreasing decrease in cross-sectional area decide.

It is understood that in addition to the rheological properties of the job mediums also the dimensions and the distribution of the outlet channels an influence on the uniformity of the material web th order medium layer. These parameters can be used in the concept tion of the distribution pipe can be easily taken into account.

According to a further aspect of the invention, the above object is achieved in an application device of the generic type in that the outlet channels deliver the application medium to the material web and that the cross-sectional area of the distribution channel on the one hand and the number and the cross-sectional areas of the outlet channels are dimensioned such that the Pressure drop in the outlet channels is greater than the pressure drop in the distribution channel. In addition to the advantage of simple construction, with respect to which reference is made to the above discussion, this embodiment variant has the further advantage of greater flexibility, both with regard to the possibility of using application media with different compositions, in particular different viscosities, and also with regard to the possibility of throughput can be controlled more flexibly through the outlet channels. Since the supply pressure predefined from the outside, for example by means of a supply pump, drops mainly at the outlet channels, one can be sure that the relative pressure conditions prevailing at the outlet channels will practically not change even when the supply pressure changes, ie, if at a supply pressure p _A the quantities M _A1 , M _{A2 are} dispensed through two specific outlet channels per unit of time, the quantities M _B1 and M _{B2 are} dispensed through the same outlet channels when the supply pressure changes to the value p _B per unit of time, however M _A1 / M _A2 = M _B1 / M _B2 applies. The same applies correspondingly when the viscosity of the application medium changes or when changing from one application medium to another.

To the advantages described above down to order media To ensure low viscosity, it is proposed that the Sum of the cross-sectional areas of the outlet channels is smaller than that Cross-sectional area of the distribution channel, preferably less than half the Cross-sectional area of the distribution channel. However, with the Invention According to the application device, only application media with a viscosity more than 2 Pa.s (2000 cP) are applied to the material web, the sum of the cross-sectional areas of the outlet channels can also be larger be than the cross-sectional area of the distribution channel.

If the outlet channels have a length of more than 5 mm and a through have a diameter of less than 10 mm, so you can order  medium an essentially orthogonal to the material web Give direction of flow, which in turn is beneficial to an equal moderate distribution of the application medium affects the material web. This "directional effect" can be further supported by that the outlet channels have a sharp edge at their outlet end Have a border.

With a view to supplying the application medium as simply as possible and a good use of the available space is for all of the embodiments discussed above suggested that the Feed opening is provided at a longitudinal end of the distribution pipe. Here can have a discharge arrangement at the other longitudinal end of the distribution pipe be provided. If, for example, 80% of the is passed through the feed opening order medium introduced into the distribution pipe via such Discharge opening again, therefore only carries about 20% of the up carrier medium on the material web, this has the advantage that ver same with a complete delivery of the supplied order medium through the outlet channels in the distribution pipe a higher flow speed is present. This higher flow rate can Sedimentation of solids in the application medium in the distribution pipe prevent. In this embodiment, the distribution pipe has one overall the working width asymmetrical shape.

At the other longitudinal end of the distribution tube, however, another can also be used Feed opening may be provided. In this case, the manifold has one arrangement symmetrical with respect to the center line of the running material web on. This embodiment has the advantage of lower feed line cross sections. To work in this case with higher flow speed can be roughly halfway between the a discharge opening can be provided in both feed openings.  

Finally, it is also possible for the distribution pipe to have a plurality of over the length of which has distributed feed openings.

The invention is based on exemplary embodiments based on the enclosed drawing will be explained in more detail. It shows:

Fig. 1 is a schematic sectional view of a first embodiment of the application device according to the invention;

Fig. 2-5 variants of distribution tubes designed according to the invention;

Fig. 6 is a view similar to Figure 1 of a further embodiment of the applicator according to the invention. and

Fig. 7 is an illustration of detail VII in Fig. 6 on an enlarged scale.

An application device according to the invention is generally designated 10 in FIG. 1. It is used to apply a liquid or pasty medium 12 to a running material web 14 which is guided around a counter roller 16 . The application device 10 comprises a distribution tube 18 with a rigid tube wall 20 which encloses a distribution channel 22 .

At its end shown on the left in FIG. 1, the distribution pipe 18 has a feed opening 24 , through which application medium is introduced into the distribution channel 22 , and at its end, shown on the right in FIG. 1, has a discharge opening 26 , through which excess application medium flows out again is distributed to the distribution channel 22 . Furthermore, the tube wall 20 comprises on its side facing the material web 14 a 20 a plurality of identical dimensioned outlet channels 28 which are arranged in the transverse direction Q at regular intervals a.

The outlet channels 28 serve to deliver the application medium 12 to the material web 14 . The cross-sectional areas of the outlet channels 28 and the cross-sectional area of the discharge opening 26 are sized such that about 80% of the introduced into the manifold 18 through the supply port 24 application medium 12 of this exit and again via the discharge opening 26 only about 20% of the coating medium through the outlet channels 28 to the material web are applied. This ensures a sufficiently high flow rate in the distribution channel 22 to prevent sedimentation of solids contained in the application medium and thus to prevent the distribution tube 18 from becoming blocked.

So that in the distribution pipe 18 along the path from the feed opening 24 to the discharge opening 26 despite the "loss" of application medium 12 through the outlet channels 28, the application medium 12 has essentially the same flow rate at all points of the distribution tube 18, in particular at all outlet channels 28 in particular essentially the same pressure conditions are present, the tube wall 20 is formed such that the cross-sectional area F of the distribution channel 22 decreases from the feed opening 24 , preferably decreases monotonously. In the embodiment shown in FIG. 1, the cross-sectional area F from the feed opening 24 to the discharge opening 26 has a constant cross-sectional area decrease, ie between two successive outlet channels 28 arranged at a distance a, the cross-sectional area F decreases by the same amount.

In Fig. 2, the manifold of another application device according to the invention is shown, which corresponds essentially to the manifold according to FIG. 1. Analog parts are therefore given the same reference numerals in the following as in FIG. 1, but increased by the number 100 .

The embodiment according to FIG. 2 is described below only insofar as it differs from the embodiment according to FIG. 1, the description of which is otherwise expressly referred to here.

In the exemplary embodiment shown in FIG. 2, the distribution pipe 118 of the application device 110 , in particular its boundary wall 120 , is designed such that the cross-sectional area F of the distribution channel 122 becomes smaller along the path from the feed opening 124 to the discharge opening 126 with increasing decrease in cross-sectional area; ie the difference between the cross-sectional areas in the two outlet channels 128 ₁ and 128 ₂ close to the feed opening is smaller than the difference in cross-sectional areas in the two outlet channels 128 ₄ and 128 ₅ near the discharge opening.

In Fig. 3, the manifold of another application device according to the invention is shown, which corresponds essentially to the manifold according to FIG. 1. Therefore, analog parts are given the same reference numerals in the following as in FIG. 1, but increased by the number 200 . The embodiment according to FIG. 3 is described below only insofar as it differs from the embodiments according to FIGS. 1 and 2, to the description of which reference is otherwise expressly made hereby.

In the exemplary embodiment shown in FIG. 3, the distribution pipe 218 of the application device 210 , in particular its boundary wall 220 , is designed such that the cross-sectional area F of the distribution channel 222 becomes smaller along the path from the feed opening 224 to the discharge opening 226 with an ever decreasing decrease in cross-sectional area; that is, the difference in cross-sectional areas in the two outlet openings 228 ₁ and 228 ₂ near the feed opening is greater than the difference in cross-sectional areas in the two outlet channels 228 ₄ and 228 ₅ near the discharge opening.

In the above-described embodiments according to FIGS. 1, 2 and 3, the distribution pipes 18 and 118 and 218 are asymmetrical in the transverse direction Q of the material web.

In Fig. 4, the manifold of another application device according to the invention is shown, which corresponds essentially to the manifold according to FIG. 1. Analog parts are therefore given the same reference numerals in the following as in FIG. 1, but increased by the number 300 . The embodiment according to FIG. 4 is described below only insofar as it differs from the above embodiments, to the description of which otherwise reference is expressly made hereby.

In the embodiment according to FIG. 4, the distribution pipe 318 of the application device 310 has a symmetrical structure with two feed openings 324 and 324 '. Starting from these feed openings, the cross-sectional area F of the distribution channel 322 decreases and reaches its minimum value in the region of the line of symmetry M. If desired, a discharge opening 326 can again be provided here.

In the embodiment according to FIG. 5, the distribution pipe 418 of the application device 410 even has three feed openings 424 , 424 ', 424 ''.

In FIG. 6, a further applicator device according to the invention is shown. In the following, analog parts are given the same reference numerals as in FIG. 1, but increased by the number 500 . The embodiment according to FIG. 6 is described below only insofar as it differs from the embodiment according to FIG. 1, the description of which is otherwise expressly referred to here.

In Fig. 6 shows an alternative embodiment of an applicator device according to the invention 510, in which the distribution channel 522 of the manifold 518 over its entire length between the supply opening 524 and the discharge opening 526 has a substantially constant cross sectional area F. In the boundary wall 520 of the manifold 518 are From passageways 528 are provided whose cross-sectional areas f are dimensioned such that the pressure drop across the outlet channels 528 is greater than the pressure drop in the distribution channel 528 between supply port 524 and the inlet end 528 a (see Fig. 7) each exit channel 528 . In this way it can be achieved that the amount of application medium 512 dispensed through the outlet channels 528 to the material web 514 per unit time can be controlled by simply increasing or decreasing the feed pressure at the feed opening 524 , and yet the relative throughput ratios at the individual outlet channels 528 im remain essentially unchanged. That is, if at a supply pressure p _A through two be outlet channels per time unit the quantities M _A1 , M _{A2 are} delivered, through the same outlet channels when changing the supply pressure to the value p _B per time unit the quantities M _B1 and M _{B2 are released} who, although M _A1 / M _A2 = M _B1 / M _B2 applies.

In order to be able to provide the pressure ratios described above for application media of low viscosity, the sum Σf of the cross-sectional areas f of the outlet channels 528 should be smaller than the cross-sectional area F of the distributor channel 522 , preferably less than half of the cross-sectional area F. Target with the application device 510 executed gene only application medium a viscosity greater than 2 Pa.s (2000 cP) are applied to the material web 514, the sum Σf, the cross-sectional areas f of the outlet channels 528 may also be larger than the cross-sectional area F of the distribution 522 .

The uniformity of the line application of the application medium 512 onto the material web 514 is also influenced by the shape of the outlet channels 528 . A uniform application layer results in particular when the application medium 512 emerges from the outlet channel 528 essentially orthogonally to the material web 514 , as is indicated in FIG. 7 by the solid arrow. This can be achieved, for example, in that the length l of the outlet channel is greater than 5 mm and the diameter d of the outlet channel is less than 10 mm. It also has a positive effect if the outlet channels have a sharp-edged boundary edge 528 c at their outlet end 128 b. This can be achieved, for example, in that the outlet channels 528 have essentially constant cross-sectional areas a up to the outlet end 528 b and are not, as shown in broken lines in FIG. 7, countersunk on the outlet side.

It is understood that the same value is the sum of the cross-sectional areas of the outlet channels on the one hand with a large number of outlet channels small cross-sectional area and secondly a small number of Outlet channels are obtained in accordance with a larger cross-sectional area can. It is also understood that a plurality of channels are smaller Cross-sectional area compared to a channel, its cross-sectional area corresponds to the sum of the cross-sectional areas of the plurality of channels, against a viscous medium a greater flow resistance puts.

Claims (14)

1. Device ( 10 ) for direct or indirect application of liquid or pasty application medium ( 12 ) to a material web ( 14 ), in particular made of paper or cardboard, with a distribution tube ( 18 ) running in the transverse direction (Q) of the material web ( 14 ) ,
wherein the distribution tube ( 18 ) comprises a distribution channel ( 22 ) and a rigid tube wall ( 20 ) surrounding the distribution channel ( 22 ), and
at least one feed opening ( 24 ) for application medium ( 12 ) and a plurality of outlet channels ( 28 ) arranged in the transverse direction (Q) of the material web ( 14 ) for dispensing the application medium ( 12 ) are provided in the tube wall ( 20 ), characterized in that the outlet channels ( 28 ) deliver the application medium ( 12 ) to the material web ( 14 ) and that the cross-sectional area (F) of the distribution channel ( 22 ) starting from the least one feed opening ( 24 ) decreases, the cross-sectional area acceptance is selected depending on the rheological properties of the application medium. 2. Application device according to claim 1, characterized in that the decrease in cross-sectional area at a predetermined distance from the feed opening ( 24 ) is chosen to be greater, the lower the value of the viscosity of the application medium ( 12 ). 3. Applicator according to claim 1 or 2, characterized in that the decrease in cross-sectional area increases with increasing distance from the feed opening ( 124 ). 4. Applicator according to claim 1 or 2, characterized in that the decrease in cross-sectional area decreases with increasing distance from the feed opening ( 224 ). 5. Applicator according to claim 1 or 2, characterized in that the distribution channel ( 22 ) has a constant decrease in cross-sectional area. 6. The device ( 510 ) for the direct or indirect application of liquid or pasty application medium ( 512 ) to a material web ( 514 ), in particular made of paper or cardboard, with a distribution pipe ( 518 ) running in the transverse direction (Q) of the material web ( 514 ) ),
wherein the distribution pipe ( 518 ) has a distribution channel ( 522 ) and a pipe wall ( 520 ) surrounding and surrounding the distribution channel ( 522 ), and
wherein in the tube wall (520) drying at least one Zuführöff (524) are for application medium (512) and a plurality of transverse direction (Q) of the material web (514) which are arranged distributed outlet channels (528) are provided for discharging the application medium (512), characterized characterized in that the outlet channels ( 528 ) deliver the application medium ( 512 ) to the material web ( 514 ) and that the cross-sectional area (F) of the distribution channel ( 522 ) on the one hand and the number and cross-sectional areas (f) of the outlet channels ( 528 ) others are dimensioned such that the pressure drop in the outlet channels ( 528 ) is greater than the pressure drop in the distribution channel ( 522 ). 7. Applicator according to claim 6, characterized in that the sum (Σf) of the cross-sectional areas (f) of the outlet channels ( 528 ) is smaller than the cross-sectional area (F) of the distribution channel ( 522 ), preferably less than half the cross-sectional area (F ) of the distribution channel ( 522 ). 8. Application device according to claim 6, characterized in that when using an application medium ( 512 ) with a viscosity of more than 2 Pa.s (2000 cP) the sum (Σf) of the cross-sectional areas (f) of the outlet channels ( 528 ) is greater than the cross-sectional area (F) of the distribution channel ( 528 ). 9. Applicator according to one of claims 6 to 8, characterized in that the outlet channels ( 528 ) have a length ( 1 ) of more than 5 mm and a diameter (d) of less than 10 mm. 10. Applicator according to one of claims 6 to 9, characterized in that the outlet channels (528) having at its outlet end (528 b) has a sharp-edged boundary edge (528 c). 11. Applicator according to one of claims 1 to 10, characterized in that the feed opening ( 24 ) is provided at a longitudinal end of the distribution tube ( 18 ). 12. Applicator according to claim 11, characterized in that a discharge opening ( 26 ) is provided at the other longitudinal end of the distribution tube ( 18 ). 13. Applicator according to claim 11, characterized in that a further feed opening ( 324 ') is provided at the other longitudinal end. 14. Applicator according to one of claims 1 to 10, characterized in that the distribution pipe ( 418 ) has a plurality of feed openings ( 424 , 424 ', 424 '') arranged distributed over its length.