EP1295987A2 - Process and apparatus for drying a moving web, particularly a coated paper or cardboard web - Google Patents

Abstract

For drying a running material web, in particular a coated paper or cardboard web, it is known to first pre-dry the web in an infrared dryer (1) with infrared emitters (4) and then to dry it further with air in an air dryer (2) , According to the invention, the air dryer (2) is operated in such a way that the heat transfer coefficient between the drying air (8) and the web (B) increases in the web running direction (L). <IMAGE>

Description

Method and device for drying a running material web, especially a coated paper or cardboard web

The invention relates to a method for drying a running material web, especially a coated paper or cardboard web in which the web first pre-dried in an infrared dryer with infrared emitters and then further dried in an air dryer with air, as well as a Device for carrying out a drying process according to the invention.

In the production of paper and cardboard webs coated with coating color are used to dry the webs after application of the coating color known drying systems used, the infrared heater or with hot air drying air dryer included. It is known to waste heat from an infrared radiator to be used in a subsequent air dryer. In the essay by summer and Aust "IR Drying Concepts for High Energy Yield" Papierfabrikation 22, 1997) describes a so-called integral dryer, at an air dryer is arranged immediately behind an infrared dryer, which Waste heat from the infrared heater is used, thus increasing the efficiency of drying. To do this, air is blown in the area of the IR radiators against the web and then aspirated. The heated air loaded with water vapor is then used as Drying air used in the subsequent air dryer.

The invention is therefore based on the object of a drying method and To provide a drying device that has the shortest possible Web length gentle drying of coated paper or cardboard webs enabled with high efficiency.

This object is achieved according to the invention in that the air dryer is so is operated that the heat transfer coefficient between the drying air and the web rises in the direction of web travel.

It has been shown in the drying of coated paper or cardboard webs that problems in the end product, such as printability, occur if the evaporation rate during drying temporarily has certain values exceeds.

When the web passes through the air dryer, the drying process is first of all with a lower one and then with a successively increasing one Heat transfer coefficient carried out. The relatively small one Heat transfer coefficient at the beginning of drying (convection drying) leads to the fact that the sudden increase in known integral dryers Evaporation rate at the beginning of convection drying is considerably lower. Exceeding that which affects the quality of the end product Evaporation rate limit is thus avoided. after the Evaporation rate has dropped sufficiently due to a drop in the web temperature the drying is carried out with an increased heat transfer coefficient, so that the same over the dryer length compared to known dryer systems Drying performance is achieved.

Convection drying with the air dryer is preferred in several stages carried out. The air dryer then contains several across the web extending and arranged one behind the other in the web running direction blowing nozzles operated that the heat transfer coefficient increases gradually.

The increase in the heat transfer coefficient is preferably brought about by that the area-specific air flow, i.e. the amount of air per time and web area, in every stage of the air dryer rises.

Alternatively, others can also influence the heat transfer coefficient Parameters are changed, for example the flow velocity of the air.

Figur 1

schematisch die Seitenansicht eines bekannten Integral-Trockners,

Figur 2

einen Trockner nach der Erfindung,

Figur 3

den Verlauf der Verdampfungsrate beim Trocknen als Vergleich zwischen den bekannten Trocknungsverfahren (Kurve 1) und den Trocknungsverfahren (Kurve 2) nach der Erfindung

Figur 4

den entsprechenden Vergleich der Bahntemperaturen beim Trocknen.

Below we explain the invention with reference to an embodiment shown in the drawing.
Show it:

Figure 1

schematically the side view of a known integral dryer,

Figure 2

a dryer according to the invention,

Figure 3

the course of the evaporation rate during drying as a comparison between the known drying processes (curve 1) and the drying processes (curve 2) according to the invention

Figure 4

the corresponding comparison of the web temperatures during drying.

As shown schematically in Figures 1 and 2, there is the inventive Drying device from an infrared dryer 1 and one in the direction of web travel L (running from left to right in the figures) air dryer arranged behind 2. The infrared dryer 1 consists of several - four pieces in the exemplary embodiment - Drying units 3 constructed, each row of infrared radiators 4th included, which are arranged with aligned radiation surfaces 4a. The infrared emitter 4 are heated with a fluid-air mixture, preferably with a gas-air mixture. In each drying unit 3, nozzles 5 are formed on the web entry side Air blown towards the track. The with exhaust gases from the radiator 4 and with steam loading air is at the outlet end of each drying unit 3 via suction openings 6 sucked off.

The air dryer 2 arranged below contains several - in Embodiment also four pieces - blow nozzles 7 with in the web running direction Are spaced from each other and across the width of the web B extend. The blowing nozzles 7 become drying air 8 against the web surface blown, which is fed via a common air hood 9. Between Blow nozzles 7 are located on the underside of the air hood 9, suction openings the air laden with water vapor is extracted. To dry one coated web, the air dryer 2 is preferably a floating dryer educated. With a float dryer are above and below the web or blow nozzles 7, from which drying air 8 is blown against the freely floating web B.

The integral dryer consisting of the infrared dryer 1 and the air dryer 2 is operated so that the exhaust air AL from the integral dryer 1 as Drying air 8 is used in the air dryer 2. The air dryer 2 after Embodiment does not have its own hot air generator, so that the entire Drying energy is generated by the emitters 4.

Alternatively, it is possible to use the air dryer 2 with its own hot air generator equip and the generated hot air HL exhaust air AL from the infrared dryer 1 admix.

So far, the integral dryer shown in Figure 1 is known and for example in the essay by Sommer and Aust "IR Drying Concepts for High Energy Yield" (Wochenblatt für Papierfabrikation 22, 1997). With the known Integral dryers, the same current occurs from each blow nozzle 7 of the air dryer 2 Drying air 8 out, this is in Figure 1 by the corresponding length of the arrows 8 shown.

The integral dryer according to the invention shown in Figure 2 is correct except for differences listed below with the known integral dryer Figure 1 match. The integral dryer according to the invention contains an air dryer 2, which has means to adjust the heat transfer coefficient between the Drying air 8 and the web B increasing in the web running direction L. adjust. An increasing heat transfer coefficient is preferred for Drying achieved in that the area-specific flow of drying air 8, i.e. the amount of air per time and m2 of web surface, over the length of the Air dryer 2 is set increasing. The individual Blow nozzles 7 arranged one behind the other on the exiting from them Set current of drying air 8. Each blowing nozzle preferably contains 7 on its Air inlet an air flap 10, with which the current from the air hood 9 in the Blowing nozzle 7 flowing drying air and thus also the amount of from Blower nozzle 7 exiting drying air 8 can be adjusted. Alternatively or additionally it is possible to change the exit cross section of the nozzle slots or holes 11 each Blower nozzle 7 to make variable, so that the flow of exiting drying air. 8 can be set to increase over the length of the air dryer 2.

If advantageous for the drying behavior, that between the blowing nozzles 7 extracted air stream 13, that is to say guided away from the web, the stream of supply air adapted to the respective blowing nozzles 7. This can be done, for example realize that on the underside of the air hood 9 between the blowing nozzles 7 Suction openings 12 having perforated plates 12a are attached, the Cross section of the openings 12 and / or the number of openings 12 for one increasing suction cross section increases in web running direction L.

In Figures 3 and 4, the different drying process between the known dryer according to Figure 1 (curve 1) and the dryer according to the invention shown in Figure 2 (curve 2). In Figure 3 the evaporation rate is over Dryer length (i.e. machine direction MD) shown in Figure 4 shows the web temperature over the dryer length.

As can be seen from FIG. 3, the evaporation rate increases in the known dryer at the beginning of the air dryer 2 suddenly falls to a considerable extent and falls then continuously. In the dryer according to the invention at the beginning of the air dryer 2 with a relatively low Heat transfer coefficient dried, so the evaporation rate significantly less rises and below a predetermined. Limit remains that for example, is 250 kg / hm2. Then in the second blowing nozzle 7 due to the increased flow of drying air 8 with an increased Heat transfer coefficient dried, so the evaporation rate in this Range increases. Similarly, in the next blowing nozzle 7 Heat transfer coefficient due to a further increased flow of drying air 8 increased, so that a sawtooth-sloping course of the evaporation rate arises. Since in the dryer according to the invention towards the end of the air dryer 2 there are increased evaporation rates compared to the known dryer, the overall performance of the two dryers is essentially the same. Out Figure 4 shows that the web temperature in the inventive Dryer drops more slowly than in the known dryer according to FIG. 1.

Claims (9)

Method for drying a running material web, in particular a coated paper or cardboard web, in which the web (B) is first pre-dried in an infrared dryer (1) with infrared radiators (4) and then further in an air dryer (2) with air is dried, characterized in that the air dryer (2) is operated such that the heat transfer coefficient between the drying air (8) and the web (B) increases in the web running direction (L). A method according to claim 1, characterized in that the area-specific air flow of drying air (8) increases over the length of the air dryer (2). A method according to claim 1 or 2, characterized in that exhaust air (AL) from the infrared dryer (1) is used as drying air (8) in the air dryer (2). Device for carrying out a drying process according to one of Claims 1 to 3, comprising an infrared dryer (1) with infrared radiators (4) and an air dryer (2) arranged behind it in the web running direction (L), characterized in that the air dryer (2 ) Has means to adjust the heat transfer coefficient between the drying air (8) and the web (B) increasing in the web running direction (L). Apparatus according to claim 4, characterized in that the air dryer (2) contains blowing nozzles (7) with air flaps (10), by means of which the flow of drying air (8) emerging from a blowing nozzle (7) can be adjusted. Apparatus according to claim 4 or 5, characterized in that the outlet cross section of the nozzle slots or holes (11) of each blowing nozzle (7) is variable. Device according to one or more of claims 4 to 6, characterized in that drying air (8) can be fed to the blowing nozzles (7) via a common air hood (9). Device according to one or more of claims 4 to 7, characterized in that exhaust air (AL) from the infrared dryer (1) can be mixed with the drying air (8) of the air dryer (2). Device according to one or more of claims 4 to 8, characterized in that there are suction openings (12) on the underside of the air hood (9) between the blowing nozzles (7), the cross section of the suction openings (12) and / or their number enlarged for a rising suction cross-section in web direction (L).

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