DE4229804A1 - Device for generating an air flow system for the treatment of continuous sheet material - Google Patents

Abstract

Apparatus for the formation of an air flow system for the treatment of running web-like material, air flows directed towards the running material web (2) being formed by means of fans (6), characterised in that it consists of interconnectable segments which in each case have at least one transverse-flow fan (6) arranged transversely to the conveying direction of the material web (2) and a nozzle unit (7) with two nozzle slots (7a, 7b) running parallel to the fan axis (6a), each transverse-flow fan (6) forming, together with a nozzle unit (7), a modular air flow element (5) which works independently of further air flow elements (5) of a segment. <IMAGE>

Description

The invention relates to a device for generating an airflow system for the treatment of by running web-like material, whereby air flows by means of Fans are generated by a nozzle system from different directions against the one to be treated Are well directed.

DE-29 08 348 A1 was a floating dryer for material webs, its housing in the web guide plane is divided such that the two parts are apart are otherwise drivable, in particular both housings share a radial blower with this inside assigned heating for heating and feeding the air through channels leading to the nozzle boxes have and each radial fan with a side wall parallel to the web guide level and to the web  Running direction of the vertical axis is arranged. This Floating dryer is characterized in that the from the radial fan, in the upper part of the housing above and / or in the lower housing part below the Nozzle boxes from the side wall to the middle of the housing changing channels on the front of the housing into one arranged above or below the nozzle boxes and channel leading to the opposite end pass to which the nozzle boxes are connected.

These and similar known devices have been significant Disadvantages: They have a large overall height and therefore require very high operating rooms, in particular in systems in which there is insufficient room length the path of the goods to be treated in several floors must run on top of each other. Such devices are so not only because of their large volume of construction, but also also very expensive and only because of its large space requirement difficult to adapt to existing premises.

Another disadvantage is that the one Fan going out to the nozzles branch out air distribution system very high energy losses caused. The air distribution in the individual areas of the nozzle system both with respect Lich the air speed, as well as the exit the desired amount of uniformity. There the return air flow is discharged laterally, the Air speed lower in the peripheral areas are held so that the continuous to be treated web-like material does not flutter around the edges. The lead is the return air flow over the side edges to a considerable extent due to the high energy losses shares.

Because of the high energy losses in distribution and Feedback system is a very powerful ven tilator required. This causes in connection  with the air distribution system very noisy operation Sounds.

After all, the end links are also in the air distribution system, namely that against the path of the pass well-directed blow nozzles in the well-known Forms unsatisfactory. These exist at known devices from across the web conveyor tion, arranged in pairs Slits.

DE-26 15 258 C2 describes a device for welding benden guiding material webs known, the Cross sections of the two slots of each limbo nozzle are different sizes. The blowing directions of the the slots of a nozzle are directed towards each other and at different angles against the to be promoted web-shaped material inclined such that the Blowing direction in the conveying direction of the material passing through is inclined flatter than that against the conveying direction inclined blowing direction. They have in Förderrich sloping slots have a larger cross section than the slots inclined against the conveying direction. In order to is a quiet, flutter-free run of the web moderate good can be achieved. However, such nozzles are has considerable problems. For one thing is hers Complicated manufacturing in the required dimensional accuracy graced and expensive. On the other hand, the dimensions of the Slots under the influence of the blowing air carried heat.

DE-26 13 135 C3 discloses an air cushion nozzle, at which kept the nozzle outlet cross-sections constant can be. This is achieved in that the Nozzles are designed as rows of holes, the holes each row on the side towards the center of the nozzle from a common baffle and in the rest of the area  separated from the edges by webs Edge cutouts in one leg of the nozzle housing be formed, which is under tension and itself supported with the webs on the guide plate. The nozzle openings thus formed cause considerable turbulence in the blown air currents adversely affect the promotion of continuous Impact material web. They also cause Nozzles very high energy losses.

The invention has for its object a Vorrich tion at the beginning of the description and in the generic term to create the designated genus at the above-mentioned shortcomings of the known Vorrich conditions of this type are largely eliminated. The construction Height should be reduced considerably, so that less Building space requires the entire device should be much better different spatial conditions and can be adapted to different output sizes NEN than the known devices of this type Energy needs should be combined with increased performance be reduced, in particular by the fact that unnecessary Energy losses are largely avoided by an optimal guidance of the air flows, which also affects a reduction in operational noise. In creating an optimal flow of air the blow nozzles that are designed in this way must be included the should that they are cheaper with optimal airflow can be produced than the known nozzles of this type.

The object is achieved according to the invention solved that a device for generating an air power system for the treatment of continuous web-like material with the features according to claim 1 Is provided.  

Further details of the invention are given in the An sayings 2 to 13.

The invention is based on a playing drawing, for example. Show it:

Fig. 1 a schematic longitudinal section through a segment of an inventive device in the form of a flotation dryer,

Fig. 2 is a cross section along the line AA in Fig. 1,

Fig. 3 shows a schematic longitudinal section through a dryer with carrier rolls,

Fig. 4 is a schematic longitudinal section through a dryer with sliding nozzles,

Fig. 5 shows a cross section through the nozzle area of an air flow element.

In the embodiment of the invention shown in FIG. 1 in the form of a segment of a welding dryer for web-like material, the segment has a box-shaped housing 1 with heat-insulating walls. At the level of the guide plane of the web-like material - hereinafter referred to as material web 2 - a slot-shaped inlet opening 3 and a slot-shaped outlet opening 4 are provided in each case in the inlet-side end wall 1 a and in the outlet side end wall 1 b. The two end walls 1 a, 1 b are equipped with conventional means for connection to the respective segment before and after.

In the segment three airflow members 5 are arranged above the material web 2 with blowing direction downwards and below the material web 2, three additional air flow elements 5 are arranged with the blowing direction upwards.

All airflow elements 5 are structurally identical. Each airflow element 5 contains a Querstromventi fan 6 and a nozzle unit 7 , each with two parallel to the fan axis 6 a extending nozzle slots 7 a, 7 b. The two nozzle slots 7 a, 7 b have a cross section of the same size, which is in each case delimited by two sheet metal walls 8 , 9 running parallel to one another. The blowing direction of both nozzle slots 7 a, 7 b are directed at an equal angle to the conveying plane of the material web 2 running through it. Between the two sheet metal walls 8 , 9 , each delimiting the cross section of a nozzle slot 7 a, 7 b, are arranged elements of sheet metal strips 10 , 11 which stabilize the air flow in the blowing direction and are made of sheet metal strips 10 , 11 which are corrugated in the blowing direction and run in the blowing direction. Instead of one each over the entire nozzle slot length by going corrugated sheet metal strip 10 , 11 , several sections of such a corrugated sheet metal strip inserted at certain intervals from one another can also be inserted.

The two mutually facing sheet metal walls 9 of the nozzle slots 7 a, 7 b together with a space between the two nozzle slots 7 a, 7 b in the plane of the nozzle orifices parallel to the conveying plane of the mate rialbahn 2 bridging nozzle plate 12 is a one-piece component, whereby the sheet metal walls 9 converge inside the air flow element 5 above the cross-flow fan 6 .

Between the air flow elements 5 above and below half the conveying plane of the material web 2 Heizele elements 13 are arranged for heating the blown air. From the nozzle slots 7 a, 7 b passing exhaust air is not beyond the side edges of the material web 2, but on the outer edges of the nozzle slots 7 a, 7 b by the heating elements 13 through the cross-flow fans 6 is supplied again.

In the embodiment shown in Fig. 3 below the material web 2 instead of air flow elements with upward blowing air flow support rollers 14 are arranged, of which the mate rialbahn 2 is carried. Here are seen between the support rollers 14 as well as between the Luftstromelemen th 5 above the web 2 heating elements 13 before.

In the illustrated in Fig. 4 Embodiment 2 Luftstromele are elements 5 with an upwardly directed air flow and heating elements 3 are disposed just below the material web, the material web 2 is supported by the nozzle units 7.

To tend to form longitudinal folds in webs of the material has a width stretch To achieve an effect, the air flow in the blower directional stabilizing channels also from the central area be more or less oblique to the outside.

With easily conveyable web material, the Air flows even without guide channels with the cross alone electricity blowers are performed.

Due to the performance characteristics of the cross power blowers can be operated with little effort Use large amounts of air in the nozzles. There is a particularly gentle drying at high Given heat transfer.

Result from the modular structure of the device there were no existing technical construction options ten with regard to the web guide: This is how the goods can track not only approximately horizontal, slightly inclined or vertically, but also in curves up to Circular arcs.  

Each formed from a nozzle-blower unit Modules can only be used without a heat generator Guidance of webs can be used without separate blowers are required.

Claims (13)

1. Device for generating an air flow system for the treatment of continuous web-like material, air flows being generated by means of fans which are directed through a nozzle system from different directions against the continuous material web, characterized in that it consists of interconnectable segments, each of which at least one transverse to the conveying direction of the web-like material (material 2) arranged cross-flow fan (6) and a nozzle unit (7) with two parallel to the fan axis (6a) extending nozzle slots (7 a, 7 b) having, or two rows of hole-type nozzles, wherein each cross flow fan ( 6 ) together with a nozzle unit ( 7 ) forms a modular, functionally self-contained, independent of other air flow elements of a segment working air flow element ( 5 ). 2. Apparatus according to claim 1, characterized in that a segment holds several airflow elements ( 5 ) ent, which are housed together in a closed housing ( 1 ), which level with the guide level of the web-like material (web of material 2 ) on the inlet-side end wall and each has a slot-shaped opening ( 3 , 4 ) on the outlet-side end wall for the passage of the material web ( 2 ), the inlet-side opening ( 3 ) of the fresh air supply and the outlet-side opening ( 4 ) simultaneously serving as exhaust air outlet. 3. A device according to any one of claims 1 or 2, characterized in that in a segment at least one air flow element (5) above the continuous web of material (2) with the blowing direction downwards and at least one air flow element (5) below the material web (2) with Blow direction are arranged upwards. 4. Device according to one of claims 1 or 2, characterized in that a plurality of air flow elements ( 5 ) above the material web ( 2 ) with blowing direction down and below the material web ( 2 ) several supporting rollers ( 14 ) are arranged in a segment. 5. Device according to one of claims 1 or 2, characterized in that a plurality of air flow elements ( 5 ) are arranged below the material web ( 2 ) with the blowing direction upwards, wherein above the material web ( 2 ) in the housing ( 1 ) there is a free space. 6. Device according to one of claims 1 to 5 for drying sheet-like material, wherein each segment surrounded by a housing ( 1 ) has a plurality of air flow elements ( 5 ) arranged one behind the other at regular intervals in the conveying direction, characterized in that between the air flow elements ( 5 ) Heating elements ( 13 ) for heating the air streams are arranged, the housing ( 1 ) having heat-insulating walls. 7. Device according to one of claims 1 to 6, wherein the air outlet openings of each nozzle unit ( 7 ) consist of two nozzle slots ( 7 a, 7 b), the blowing directions of which are inclined towards the conveying plane of the material web ( 2 ) towards one another, characterized in that

• - Both nozzle slots ( 7 a, 7 b) have the same cross-section, the nozzle cross-sections being delimited by two sheet metal walls ( 8 , 9 ) running parallel to one another,
• - The blowing directions of both nozzle slots ( 7 a, 7 b) are inclined at an equal angle to the conveying plane of the material web ( 2 ),
• - At least one of the two nozzle slots ( 7 a, 7 b) between the two sheet metal walls ( 8 , 9 ) delimiting the nozzle cross section is arranged at least one element stabilizing the air flow in the blowing direction.

8. The device according to claim 7, characterized in that a between the two the nozzle cross-section sheet metal walls ( 8 , 9 ) arranged, the air flow in the blowing direction stabilizing element from a corrugated to the blowing direction, in the blowing direction channels forming sheet metal strip ( 10 , 11th ) consists. 9. The device according to claim 8, characterized in that in at least one of the two nozzle slots ( 7 a, 7 b) the air flow stabilizing corrugated sheet metal strip ( 10 , 11 ) is divided into several sections arranged at intervals from one another. 10. Device according to one of claims 7 to 9, characterized in that between the two nozzle cross-section be bordering sheet metal walls ( 8 , 9 ) arranged, the air flows in the blowing direction stabilizing elements from the central region in the conveying direction inclined outward channels. 11. The device according to one of claims 1 to 10, characterized in that the two mutually facing sheet metal walls ( 9 ) of the nozzle slots ( 7 a, 7 b) together with one the space between the two nozzle slots ( 7 a, 7 b) in the Level of the nozzle mouths parallel to the conveying plane of the material web ( 2 ) bridging nozzle plate ( 12 ) form an integral component. 12. The apparatus according to claim 11, characterized in that the nozzle plate ( 12 ) is provided at least in the vicinity of the rear nozzle slot in the conveying direction ( 7 a) with air passages. 13. The apparatus according to claim 12, characterized in that the sum of the cross sections of the air passages in the nozzle plate ( 12 ) in the vicinity of the rear nozzle slot in the conveying direction ( 7 a) is larger than in the remaining surface of the nozzle plate ( 12 ).