DE3716468A1 - DEVICE FOR DRYING RELEASED MATERIAL COATINGS BY MEANS OF FREE-DETACHED AIR CUSHION NOZZLES - Google Patents

Description

The invention relates to a device for Drying free material webs by means of Air cushion nozzles, between their nozzle slots (rows of holes) one perforated each, especially to the material web convex curved plate is arranged, the two between them an air cushion forming air jets each air cushion nozzle has different angles of inclination middle management level of the material web and possibly the Nozzle slots have different cross sections.

The quality of a device for drying Material webs are not only affected by the drying performance, but also and in many cases predominantly on it measured whether the material web through which it is applied Blown air is guided stably. Since material webs with different characteristics with free leadership must be dried, it is understood that in Depending on the properties of the material web Demand for stable leadership is not always full  can be met satisfactorily. During material webs, that have a certain surface stability, such as finished papers or foils, usually with those for today Available air cushion nozzles or wing nozzles can be managed satisfactorily Material webs that have only a low surface stability have, like knitted fabrics, no suitable blow nozzles Available. However, there are also difficulties with everything else reasonably easy to lead material webs, if there are sudden changes in leadership, such as Differences in humidity and differences in paper or heat for foils. Those due to these changes Deformations of the material web, but also changes in the Nozzle slots in the blast air nozzles can affect aerodynamics so disturbed that stable guidance is not guaranteed is.

Attempts have been made to get the problems under control get, for example, asymmetrical Air cushion nozzles are used in which the Blow blasting with each air cushion nozzle blow on the material web at different angles of inclination, but it has been shown in practice that even with such Nozzles clear flow conditions from the above reasons mentioned cannot always be observed, rather, there was a change in the outflow Blown air from a long side of the blown air nozzle onto the other side.

The known edge flutter is particularly problematic Material webs, which is due to the fact that from the Air cushion Air flows out to the edges of the material web. Try using one perforated over its entire area Plate between the nozzle slots, through their perforation Blown air has been blown into the air cushion  no satisfactory results. Through the single, emerging from the perforation Blowing air jets also becomes the flow behavior the blowing air coming out of the nozzle slots is disturbed, which in turn worsened leadership traits brings. This is especially true when the distance increases the web of material from the perforated plate because in in this case, the one decisive for the guidance of the material web Overflow is particularly disturbed.

The object of the invention is a device for drying of free, in particular suspended, material webs by means of air cushion nozzles, at which too problematic material webs with a high Stability.

This task is the beginning of a device mentioned type in that the nozzle slots a each air cushion nozzle from the middle management level of the Material web have such different distances and the perforated plate arranged between the nozzle slots is so inclined to the management level that on one long side of the air cushion nozzle Outflow of the blowing air results, and that behind the perforated plate a storage chamber is arranged.

In contrast to known asymmetrical air cushion nozzles, where the asymmetry is due solely to the inclination of the Blowing direction of the two nozzle slots and / or their Cross section was achieved in the invention Geometry of the air cushion nozzle in relation to the middle one Management level of the material web mainly through the different distance of the nozzle slots from the middle management level and the inclined arrangement of the perforated plate. Beyond that, it won't  as in the prior art from the entire perforation the plate of air in the space between the material web and blown out of the plate, rather air can escape from this space flow into the stowage chamber under the plate, so that a dynamic pressure can build up here ensures that in the area of the web edges through the Perforation blown air that flows out the air from the space between the material web and the perforation disturbs. It was found that through the common application of the above characteristics the leadership characteristics of the Air cushion nozzle can be improved significantly because the perforated plate allows undisturbed overflow and thus also the prerequisite for the defined outflow one side without risk of turning over and above also ensures that there is no one around the edges Edge flutter comes. This improvement for leading the Material web does not even require a larger one device engineering effort than the known Air cushion nozzles. Finally, with the air cushion nozzle according to the invention also an improvement in Achieve heat transfer.

Through the cross section of the perforation in the plate and the cross section of the storage chamber can be a specific one Efficiency range and strength in the area of the material web edges to adjust. Preferably, the distance is Bottom of the storage chamber from the perforated plate 4-12% the distance between the two nozzle slots. As cheap turned out to be the cross section of the perforation at least equal to the sum of the cross sections of the Nozzle slots and is 4-12% of the plate surface.

Because the blow air jet from the nozzle slot with the smaller one clearance serves to form the air cushion above the perforated plate to allow  on the other hand, it should allow an outflow one of these requirements favoring the Invention provided that the transition from the perforated Plate in the neighboring nozzle lip of the nozzle slot smaller cross-section a tear-off edge for the flow forms. It turned out to be favorable if the Radius of curvature of the transition is smaller than the width of the slot is. It is important that the blown air jet is off the nozzle slot with the larger clear width, which in the space between the material web and the perforated Blowing plate, is able to blow the jet of air out of the Deflect the nozzle slot with the smaller clear width.

It is known that it is necessary for a stable management of Material web is cheap if the material web is wavy. For this purpose, the Invention provided that when on both sides of the Arranged material web and in the material web running direction air cushion nozzles offset against each other the nozzle slot larger cross-section and possibly flatter inclination of the Blower jet a greater distance from the Material web guide level of the material web has. Especially in this arrangement, in addition to the one sought, is special stable guidance of the material web also a high Heat transfer coefficient achieved. With this configuration is preferably the transition from the perforated plate larger in the adjacent nozzle lip of the nozzle slot Cross-section formed as a tear-off edge for the flow. The blown air jet can therefore be of the type Free jet nozzle act on the material web through which he in the space between the material web and the perforated plate is deflected.

Unless it has a high heat transfer coefficient arrives, but in addition to the stable guidance of the material web  the lock function is in the foreground, like it for example at the entrance to a dryer provided according to an embodiment of the invention that the Air cushion nozzles on both sides of the web are arranged opposite, the nozzle slot larger cross-section and possibly flatter inclination of the Blow a smaller distance from the middle Guide level of the material web than the other nozzle slot and has the inner nozzle lip of the nozzle slot larger cross-section convex in the perforated plate passes so that the blown air jet due to the Coanda effect attaches itself to the perforated plate.

When using offset and oppositely arranged air cushion nozzles, e.g. B. in one Dryers, are the opposite Air cushion nozzles at the entrance and end of the drying section and the offset air cushion nozzles in the intermediate area, the Air cushion nozzles with their downstream side of the middle of the Drying section are facing. With one Arrangement you get defined flow conditions, the individual air cushion nozzles do not interfere, but support each other in guiding the blown air.

It is also an advantage if in the middle of the Drying section with symmetrical air cushion nozzles on the plates arranged between the nozzle slots arranged bluff bodies are provided.

The clear flow conditions to achieve a stable material guide can be used in conjunction with Heating elements in the form of spotlights can be used. So is provided in one embodiment of the invention that between two air cushion nozzles in a row  directional outflow side a heating element in the form of a Emitter and in the outflow direction of the blown air from the Air cushion immediately in front of the second air cushion nozzle Outflow channel is arranged.

In the following the invention with reference to a drawing explained in more detail. In detail shows

Fig. 1 shows part of an asymmetric Luftkissendüse with about guided material web in cross-section,

Fig. 2 shows the asymmetric Luftkissendüse of FIG. 1 in front view,

Fig. 3 two oppositely arranged asymmetrical air cushion nozzle, in a variant to Fig. 1 geometric arrangement in cross-section

Fig. 4, two asymmetrical air cushion nozzles in one to FIG. 1, other geometric arrangement with a heating element arranged between them

Fig. 5 shows a part of the dryer section of a dryer with asymmetrical air cushion nozzles arranged on both sides in a side view in a schematic representation and

Fig. 6 shows a part of a symmetrical air cushion nozzle in cross section.

The Luftkissendüse according to Fig. 1 and 2 has an asymmetrical structure. In relation to a central guide level 1 , to which a web 2 has an undulating course, two slot nozzles 3, 4 are at different distances. The slot nozzle 3 , which has a cross section that is many times larger than the slot nozzle 4 , is at a greater distance from the guide plane 1 than the smaller slot nozzle 4 . The angle of inclination of the blown air jet 5 emerging from it is also less steep than that of the blown air jet 6 of the smaller slot nozzle 4 .

Between the inner die lips 7, 8 of the two slit nozzles 3, 4 is disposed a perforated convexly curved to the material web 2 plate 9 of which the die lip 7 of adjacent area 9a forms an acute angle with the guide plane 1 and its die lip 8 adjacent area 9 b to the management level 1 is substantially parallel. This results in an oblique position of the perforated plate 9 . The inclined position is such that the distance of the slot nozzle 3 from the guide plane 1 is approximately five times the slot width.

The cross section of the perforation of the perforated plate 9 on the entire plate surface is 4-12% and is at least equal to the sum of the cross sections of the slot nozzles 3, 4 . Below the perforated plate 9 there is a storage chamber 10 , the bottom 11 of which is at a distance from the perforated plate 9 , which is 4-12% of the distance between the two slot nozzles 3, 4 .

In such Luftkissendüse the air jet 5 is incident as a free jet onto the material web 2 and is deflected by it in the direction of the slot. 4 The resistance of the blown air jet 6 creates a jam, but the blown air jet 6 cannot withstand the dynamic pressure due to its small cross section and its steep incline, but instead flows deflected with the air out of the air cushion. A small part of the jammed air reaches the stowage chamber 10 via the perforation and flows to the two ends of the stowage chamber 10 . Only in the outer area, where the material web 2 no longer covers the perforated plate 9 , can the air escape again through the perforation of the plate 9 . The blown air escaping through the exposed perforation has the special effect that it interferes with the blown air component flowing out of the air cushion area between the perforated plate 9 and the material web 2 towards the edges of the material web by braking and thereby prevents this blown air component from fluttering around the edge of the material web 2 to effect.

The perforated plate 9 and the storage chamber 10 can be designed in various ways. It is also possible to retrofit air cushion nozzles with an asymmetrical structure with perforated plates and to position them in relation to the guide level in such a way that, in principle, the structure is the same.

. In the embodiment of Figure 5, several air cushion nozzles. 12 - 19 of the type shown in Figures 1 and 2 offset on both sides of a web of material 20 to form a drying section in the running direction of the material web to each other. The special feature of this arrangement is that the outflow side of the individual air cushion nozzles are on the side facing the center M. This ensures that when installed in a dryer there is no excessive flow pressure to the outside at the inlet and outlet slots. So that the flows directed towards each other in the center M do not interfere with this arrangement, blocking air cushion nozzles 21, 22 are arranged in the region of the center M , which have the structure shown in FIG. 6. These air cushion nozzles have two slot nozzles 23, 24 and a plate 25 connecting the inner nozzle lips, on which a bluff body 25 a with sharp-edged steps 26 is arranged on both sides. In front of this bluff body 25 a , a jamming air cushion forms, which counteracts an overflow of blown air.

In order to prevent blow air from escaping from the inlet and outlet slots of a dryer provided for the material web, in contrast to conventional air cushion nozzles, it is also possible to arrange air cushion nozzles according to the invention on opposite sides of the web, which in principle have the same structure as the air cushion nozzles according to FIG . have 1 and 2, but with the difference that the perforated plate 29, opposite 30 is inclined and the junction 31, 32 of the inner die lip 32, 33 of the nozzle slot 35, 36 of larger cross section in the perforated plate 29, 30 formed in such a convex is that the blowing air jet 37, 38 completely flows into the space between the material web 39 and the perforated plate 29, 30 due to the Coanda effect. In this exemplary embodiment, in contrast to the previous exemplary embodiment, the blown air jet 37, 38 does not act as a free jet and therefore does not have to be deflected from the material web 39 , but instead reaches the space between the material web 39 and the perforated plate 29 solely because of the Coanda effect . 30th The undisturbed overflow of the perforated plate 29, 30 and the effect of blown air escaping from the stowage chamber 40, 41 in the region of the edges of the material web 39 are retained. The opposite inclination of the perforated plate 29, 30 serves to ensure that the air cushion only extends as far as the middle guide plane of the material web 39 and not into the effective area of the opposite nozzle. In the exemplary embodiment with offset air cushion nozzles ( FIG. 5), this requirement is irrelevant, since a wavy material web course is even desired here for more stable guidance.

The air cushion nozzles 42, 43 shown in FIG. 4 have the same structure as the air cushion nozzles according to FIGS. 1 and 2, however their geometric arrangement with respect to the material web 44 is different, namely that of the air cushion nozzles 27, 28 according to FIG. 3 The reason for this other geometrical arrangement is that the height of the air cushion has to be restricted in order not to push the material web 44 away from the middle guide level in the case of an arrangement on one side several times in succession. No high heat transfer is required here either, but the other properties of the air cushion nozzle according to the invention with regard to the stable guidance and in particular the edge flutter of the material web to be avoided are required. A high heat transfer is not required because, in this embodiment , an infrared radiator 45 serving as a heating element is provided between the two air cushion nozzles 42, 43 . The drying performance is therefore mainly caused by this radiator 45 and not by the air cushion nozzles 42, 43 . An outflow channel 46 is arranged between the radiator 45 and the next air cushion nozzle 43 and receives the blown air enriched with the medium of the material web 44 to be dried. The particular advantage of the simultaneous use of infrared radiators 45 and air cushion nozzles 42, 43 is that when the material web is in a stable position relative to the infrared radiators 45 , the infrared radiators 45 can be operated with the highest output because of the blowing air flowing over them and the blowing air takes over the mass transfer and thereby still provides drying performance.

Claims (12)

1.Device for drying free material webs by means of air cushion nozzles, between the nozzle slits (or rows of holes) of which a perforated plate, in particular a convexly curved material web, is arranged, both air blower jets forming an air cushion of each air cushion nozzle having different angles of inclination to the central guide plane of the material web and if necessary, the nozzle slots have a different cross section, characterized in that the nozzle slots ( 3, 4 ) of each air cushion nozzle ( 12 - 19, 27, 28, 42, 43 ) from the central guide plane ( 1 ) of the material web ( 2, 20, 39, 44 ) have such different distances and the perforated plate ( 9, 29, 30 ) is arranged so inclined to the guide plane ( 1 ) that there is a defined outflow of the blowing air on one long side, and that behind the perforated plate ( 9, 29, 30 ) a storage chamber ( 10, 40, 41 ) is arranged. 2. Device according to claim 1, characterized in that the distance between the bottom ( 11 ) of the storage chamber ( 10 ) from the perforated plate ( 9 ) is 4-12% of the distance between the two nozzle slots ( 3, 4 ). 3. Device according to claim 1 or 2, characterized in that the cross section of the perforation in the perforated plate ( 9 ) is at least equal to the sum of the cross sections of the nozzle slots ( 3, 4 ) and 4-12% of the surface of the perforated plate ( 9 ) is. 4. Device according to one of claims 1 to 3, characterized in that the transition from the perforated plate ( 9 ) into the adjacent nozzle lip ( 8 ) of the nozzle slot ( 4 ) of smaller cross section forms a tear-off edge for the flow. 5. The device according to claim 4, characterized in that the radius of curvature of the transition is smaller than the width of the nozzle slot ( 4 ). 6. Device according to one of claims 1 to 5, characterized in that arranged on both sides of the material web ( 20 ) and offset in the material web direction against each other air cushion nozzles ( 12 - 19 ) of the nozzle slot ( 3 ) larger cross-section and, if necessary, flatter inclination of the blowing jet ( 5 ) has a greater distance from the middle guide plane ( 1 ) than the other nozzle slot ( 4 ) ( Fig. 5). 7. The device according to claim 6, characterized in that the transition from the perforated plate ( 9 ) in the adjacent nozzle lip ( 7 ) of the nozzle slot of larger cross section forms a tear-off edge. 8. Device according to one of claims 1 to 5, characterized in that in on both sides of the material web ( 39 ) oppositely arranged air cushion nozzles ( 27, 28 ) of the nozzle slot ( 35, 36 ) larger cross-section a smaller distance from the central guide plane of the material web ( 39 ) than the other nozzle slot and the transition from the perforated plate ( 29, 30 ) into the adjacent nozzle lip ( 33, 34 ) of the nozzle slot ( 35, 36 ) of larger cross section forms a convexly curved guide surface ( 31, 32 ) ( Fig . 3). 9. The device according to claim 8, characterized in that the perforated plate ( 29, 30 ) with its nozzle slot ( 35, 36 ) larger cross-section adjacent area with a distance corresponding to twice the larger slot width and with its smaller cross-section adjacent area with the nozzle slot a distance corresponding to the ten times the width of the larger nozzle slot from the central guide plane of the material web ( 39 ) are arranged. 10. The device according to claim 8 or 9, characterized in that the oppositely arranged air cushion nozzles ( 27, 28 ) form the beginning and the end of a drying section and the oppositely arranged offset air cushion nozzles ( 12 - 19 ) form the intermediate region of the drying section, the air cushion nozzles with their outflow side facing the center M of the drying section. 11. The device according to claim 10, characterized in that in the center M of the drying section symmetrical air cushion nozzles ( 21, 22 ) with on a between the nozzle slots ( 23, 24 ) arranged plate ( 25 ) arranged bluff body ( 25 a) are provided. 12. Device according to one of claims 1 to 6 and 9 to 11, characterized in that a heating element ( 45 ) in the form of a radiator, in particular infrared radiator, and in the outflow direction of the blown air directly between two air cushion nozzles ( 42, 43 ) lying one behind the other with the same direction of outflow side an outflow channel ( 46 ) is arranged in front of the second air cushion nozzle ( 43 ).