EP2056052A2 - Web of material drying arrangement - Google Patents

Abstract

The arrangement (1) has a material web path (6) guided along a radiation dryer (2) in direction of motion. The radiation dryer has cylindrical radiators (3) arranged in a level (5), and the material web path running on both the sides of the level, where axes of the radiators are arranged parallel to each other. The axes of the radiators are aligned parallel to a motion direction (7). Groups of radiators are arranged one behind the other in the direction of motion, and the groups are arranged in parallel levels.

Description

The invention relates to a material web dryer arrangement having at least one radiation dryer and a material web path guided along the radiation dryer with a direction of movement.

A web dryer serves to dry a web. The invention will be described below with reference to a paper web as an example of a material web. But it is also applicable to other webs that need to be dried in a similar manner.

WO 2005/085729 A2 shows a dryer arrangement, in which the material web is passed first to two radiation dryers and then to an air dryer. This arrangement of radiation dryer and air dryer can be repeated. The radiation dryers are designed here as flat radiators.

A similar embodiment is made EP 1 169 511 known. Again, the web is passed to two surface radiators and then an air dryer.

At one off EP 0 916 915 B1 known design drier are arranged on both sides of the web.

DE 39 10 898 B4 shows a combination dryer, in which the material web is guided along a surface radiator and then through an air dryer, in which it is acted upon from both sides with warm air.

GB 965,095 shows a drying device in which a material web is passed over drying cylinders. Between individual deflection points, the web can be additionally dried by radiators. These radiators are designed as surface heating elements. If such a surface heating element is arranged between two sections of the web path, then it gives way to heat both sides. The radiator may also be insulated on one side against heat dissipation if it is not disposed between two sections of the web path.

Radiation dryers have the advantage over dryers or convection air blowers that allow relatively high heat transfer to the web to be dried. The design as a surface radiator also has the advantage that the material web can be acted upon relatively uniformly with heat. However, surface radiators have the disadvantage that a no longer negligible proportion of the energy is lost towards the back of the radiator.

The invention has for its object to achieve the best possible efficiency in a web dryer arrangement.

This object is achieved in a web dryer assembly of the type mentioned above in that the radiation dryer has a plurality of cylindrical radiators, which are arranged in a plane, and the material web path extends on both sides of the plane.

The emitters emit electromagnetic radiation, for example IR radiation (infrared radiation) or UV radiation (ultraviolet radiation). A cylindrical radiator is relatively easy to train. It emits radiant energy on all its radial sides. If the material web is now run along on both sides of the plane in which the emitters are arranged, then the power output by the emitters is absorbed almost completely by the material web, so that a good energy transfer can be achieved even without the use of reflectors and efficiency losses are reduced by the reflectors. The radiators can be operated with electrical energy or with combustion energy, for example with a gas heater. If an emitter fails or is otherwise defective, then this emitter can be easy to replace, without having to replace the entire dryer assembly.
Preferably, the axes of the radiators are arranged parallel to each other. This achieves a relatively uniform distribution of radiation in a simple manner.

Preferably, the axes of the radiators are directed parallel to the direction of movement. In this case, one can use relatively low-cost spotlights, because it is no longer necessary that the radiators have a uniform energy output over their entire length.

Preferably, a plurality of groups of radiators are provided, wherein the radiators of a group are arranged in gap to radiators of another group. In general, it is necessary to arrange the adjacent radiators with a small distance to each other in order to avoid mutual damage due to excessive heat density. If you now arranges the radiator in different groups and arranges the radiator in the different groups on gap to each other, then you can still achieve a relatively uniform drying performance across the width of the web.

It is preferred that the groups are arranged one behind the other in the direction of movement. The radiators can then be arranged in a plane as before. The individual regions of the material web are then optionally heated successively, depending on which group of radiators the material web passes in an instant.

Alternatively or additionally, it may be provided that the groups are arranged in parallel planes. In this case, the radiators of one group radiate through the gaps between the radiators of the other group. Also in this way a very good energy yield can be ensured. Preferably, the axes are aligned in the direction of gravity. The sections of the material web which are dried by the material web dryer arrangement also run vertically in this case. This has the advantage that the moisture released by the Material web evaporates, can flow unhindered. Moreover, it is possible in this embodiment in a simple manner to absorb waste heat and continue to use.

The material web path preferably has at least one non-contact deflection device between its sections on both sides of the plane. This is particularly advantageous if the material web has been provided with a coating which is to be dried by the material web dryer arrangement. In this case, the material web initially runs along one side of the plane with the radiators and is dried. Even if the coating has not yet been dried to its full extent, the material web can then be deflected by the non-contact deflection device in such a way that it can also be guided past the radiators on the other side of the plane. This makes it possible to achieve an excellent energy yield.

Preferably, the deflection device has a deflection radius which is greater than half the distance of the sections perpendicular to the plane. This embodiment has two advantages. On the one hand, the stress of the material web is smaller, because the deflection radius is greater. Nevertheless, it is possible to pass the material web relatively close to the radiators. The more dense the material web can be brought to the radiator, the better the heat transfer efficiency. On the other hand, the time required for changing the direction of the web can be extended, so that the temperature in the web, if necessary, can even out before the web is heated again by the radiator. In addition, moisture can evaporate when deflecting, which has been evaporated by the radiator.

Preferably, the deflection device is designed as an air drying device. In the deflection can be added additional heat energy in the web, which further improves the drying process.

It is preferred that the deflection device comprises gas nozzles which are acted upon by gas, which is heated by means of the radiator. So you use the waste heat of the radiator to heat the deflection. Thus, in the simplest case, cooling of the material web during deflection is avoided. In the best case, an additional drying power is transmitted to the material web by the waste heat of the radiator.

The air drying device preferably has an air duct with a connection between supply air and exhaust air. In the air drying device, it is thus possible to recirculate the air (or another gas), so that a good thermal efficiency can be achieved. The air usually does not cool down to the ambient temperature when the material web is deflected during the deflection, so that less energy is required to bring it again to the temperature desired for drying. For this purpose, the waste heat from the spotlights is often sufficient.

If this is not the case, the air duct can advantageously have an additional heating. With the additional heating, it is possible to bring the air for the deflection again to the desired temperature.

Fig. 1

eine erste Ausgestaltung einer Materialbahntrockneranordnung in Seitenansicht,

Fig. 2

eine zweite Ausgestaltung einer Materialbahntrockneranordnung in Vorderansicht,

Fig. 3

eine dritte Ausgestaltung einer Materialbahntrockneranordnung in Vorderansicht und in Draufsicht,

Fig.4

eine vierte Ausgestaltung einer Materialbahntrockneranordnung in Seitenansicht und

Fig. 5

eine fünfte Ausgestaltung einer Materialbahntrockneranordnung.

The invention will be described below with reference to preferred embodiments in conjunction with a drawing. Herein show:

Fig. 1

a first embodiment of a material web dryer assembly in side view,

Fig. 2

a second embodiment of a web dryer arrangement in front view,

Fig. 3

a third embodiment of a web dryer arrangement in front view and in plan view,

Figure 4

a fourth embodiment of a web dryer arrangement in side view and

Fig. 5

a fifth embodiment of a web dryer arrangement.

A web dryer assembly 1, as in Fig. 1 is shown, has a designed as an infrared radiator radiation dryer 2, which has a plurality of perpendicular to the plane of succession arranged cylindrical radiator 3. The radiator 3 can be electrically operated or gas-heated. The emitters 3 emit radiation 4, for example infrared radiation or ultraviolet radiation or another electromagnetic radiation with which thermal energy can be transmitted to a material web 6.

The radiators 3 are arranged parallel to one another in a plane 5. The radiators 3 are arranged vertically, i. parallel to the direction of gravity.

The material web 6 is guided along a material web path. A direction of movement is indicated by an arrow 7. The material web 6 is guided over a deflection roller 8 so that it can change its direction by 180 °.

The material web 6 is guided past the emitters 3 as close as possible, so that with the aid of the radiation 4 thermal energy can be transmitted from the emitters 3 to the material web 6. The material web 6 is guided on both sides of the plane 5, so that the material web is guided past both on the front side and on the back of the radiator 3. Thus, almost the entire energy radiated by the radiators 3 can be transferred to the web 6 without the use of reflectors. This leads to an increase in temperature in the web 6, which in turn leads to the moisture contained in the web 6 being able to evaporate.

Fig. 2 shows a modified embodiment of a material web dryer assembly 1 in plan view, wherein for explanation, the material web 6 has been removed so far that you can look at the radiator 3.

It can be seen that the cylindrical radiators 3 are each arranged at a distance 9 next to each other. This distance 9 is required in many cases to avoid overheating of the radiator 3. The radiators 3 are aligned parallel to the direction of movement 7. In this case, the case could occur that the web 6 in the width direction, i. between its two edges 10, 11, is heated unevenly. To avoid this, the radiators 3 are arranged in two groups 12, 13. The radiators 3 of the two groups 12, 13 are in the same plane. The radiators 3 of the group 12 are arranged so that they are located at the position of a gap 9 of the other group 13. The emitters 3 of the group 12 are arranged on a holder 14 and the emitters of the group 13 on a holder 15. By a lateral offset of the two brackets 14, 15 relative to each other, the arrangement of the radiator 3 of a group 12 on gap 9 of the other group 13 can be achieved. The emitters 3 of the two groups 12, 13 act in succession on the material web 6 in the direction of movement 7.

Fig. 3 shows a third embodiment of a material web dryer assembly 1 and in Fig. 3a according to the view of Fig. 2 , ie in supervision with partially removed material web 6 and in Fig. 3b in front view.

Fig. 3b shows that the cylindrical radiator 3 are arranged in two groups 12, 13, wherein the radiators 3 of the group 12 of a gap 9 between radiators 3 of the group 13 face. In this case, the emitters 3 of the group 12 are arranged in a different plane than the emitters 3 of the group 13. This can also be achieved that the material web 6 between its edges 10, 11 is applied uniformly with thermal energy. The radiators 3 of both groups 12, 13 can be arranged in this case on a holder 14. But it is also possible to arrange them on different brackets, by a lateral offset of the Brackets 14, 15 to achieve the desired orientation of the radiator 3 to gap 9.

Out Fig. 3b It can be seen that the material web 6 can be guided relatively close to the radiators 3.
Fig. 4 shows an embodiment in which a material web 6, for example a paper web, in a coating device 16 on one side 17 is provided with a coating, for example a line. The side 17 faces the radiators 3. As the web 6 passes the radiators 3, it is dried on the coated side 17.

However, the page 17 is often not dried to a sufficient extent after passing the emitters 3 for the first time. The material web 6 is therefore deflected without contact in a non-contact deflection device 18. The deflection device 18 has a plurality of air nozzles 19, which are directed against the side 17 of the material web 6. The air nozzles are supplied by a fan 20 which directs the air (or other gas) to the web 6 with sufficient pressure to support the web 6. The blower 20 is arranged in the direction of gravity above the radiator 3 and takes with the aid of a guide 21 shown schematically air or - in the case of gas-heated radiators - and the heated combustion exhaust gases from the environment, which have been heated by the radiator 3. This is essentially convection, i. the radiant energy transmitted to the web 6 is practically not reduced.

As a result of the fact that the air ejected from the air nozzles 19 has been heated by the radiators 3, drying takes place even during the deflection in the deflection device 18. In addition, the air ejected from the air nozzles 19 can carry away moisture which is still present on the side 17 of the material web 6.

The deflection device 18 has a deflection radius that is greater than half the distance between the two sections 22, 23 of the material web 6 on both sides of the plane 5, i. the material web 6 is initially moved away from the plane 5 by two deflection rollers 24, 25 which act on the uncoated side of the material web 6. As a result, the material web 6 is guided around the deflection device 18 with a wrap angle of at least 180 °, preferably even more, for example 300 °. Since the deflection radius is greater than half the distance between the two sections 22, 23, the load caused by the deflection of the material web 6 is kept small. The deflection radius is preferably two to four times half the distance between the two sections 22, 23. Despite the large deflection radius, it is possible to pass the material web 6 relatively close to the radiators 3.

Fig. 5 shows a fifth embodiment of a web drying device 1, which is substantially the of Fig. 4 equivalent. Added is an air duct system 26 with an exhaust air 27 and a supply air 28 for the deflecting device 18, which is also formed in this case as an air drying device. Supply air 27 and exhaust air 28 are connected by a connection 29 with each other. In the connection, a blower 30 is arranged to circulate the air through the deflector 18. In the supply air 28, a heater 31 is arranged to bring the air in the deflector 18 to an elevated temperature when the heating by the radiator 3 is not sufficient.

Part of the exhaust air is removed from the circuit through an exhaust air outlet 32. For a fresh air inlet 33 fresh air is supplied. The positions of exhaust air outlet 32 and fresh air inlet 33 are shown here only symbolically. The actual design depends on the circumstances, in particular the number of available fans.

Again, the web 6 is first dried on its coated side 7 by the radiator 3, where it is passed relatively dense. Thereafter, the coated side 17 of the web 6 during deflection in the deflection 18 dried by air, which is ejected from the air nozzles 19. After passing through the deflecting device 18 designed as an air-drying device, the material web 6 is once again conducted past the emitters 3 in order to be dried by radiant energy.

In a manner not shown in the case of coating drying of the device according to the invention can still follow a Nachverdunstungsstrecke, for example an air dryer.

Claims (13)

Material web dryer arrangement comprising at least one radiation dryer and a material web path guided along the radiation dryer with a direction of movement, characterized in that the radiation dryer (2) comprises a plurality of cylindrical radiators (3) arranged in a plane (5) and the web path (6) both sides of the plane (5) runs. Material web dryer arrangement according to claim 1, characterized in that the axes of the radiators (3) are arranged parallel to each other. Material web dryer arrangement according to claim 1 or 2, characterized in that the axes of the radiators (3) are directed parallel to the direction of movement (7). Material web dryer arrangement according to one of claims 1 to 3, characterized in that a plurality of groups (12, 13) of radiators (3) are provided, wherein the radiator (3) of a group (12, 13) on gaps (9) to radiators (3 ) of another group (13, 12) are arranged. Material web dryer arrangement according to claim 4, characterized in that the groups (12, 13) in the direction of movement (7) are arranged one behind the other. Web dryer assembly according to claim 4 or 5, characterized in that the groups (12, 13) are arranged in parallel planes. Material web dryer arrangement according to one of claims 1 to 6, characterized in that the axes are aligned in the direction of gravity. Material web dryer arrangement according to one of claims 1 to 7, characterized in that the material web path (6) at least one non-contact deflecting device (18) between its sections (21, 23) on both sides of the plane (5). Material web dryer arrangement according to claim 8, characterized in that the deflection device (18) has a deflection radius which is greater than half the distance of the sections (22, 23) perpendicular to the plane (5). Material web dryer arrangement according to claim 8 or 9, characterized in that the deflection device (18) is designed as an air drying device. Material web dryer arrangement according to one of claims 8 to 10, characterized in that the deflection device gas nozzles (19) which are acted upon by gas, which is heated by means of the radiator (3). Material web dryer arrangement according to claim 10 or 11, characterized in that the air drying device has an air guide with a connection (29) between supply air (28) and exhaust air (27). Material web dryer arrangement according to claim 12, characterized in that the air duct has an additional heater (31).

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