The present invention relates to a method for ensuring the run of the web in the multi-cylinder dryer of a papermachine, as set forth in the preamble of claim 1. The invention relates also to a device "for carrying out the above method, as- set forth in the preamble of claim 7.

The multi-cylinder dryers of a papermachine have employed a so-called twin-wire run at the downstream end of a drying section. In the twin-wire run, the wire is supported against the jackets of cylinders included in two tiers of cylinders by means of two wires, one running along a tortuous path against the jackets of cylinders of an upper tier and the other against the jackets of cylinders of a lower tier. When passing over from one tier of cylinders to the other, the web travels unsupported. At machine speeds of more than 800 m/min, the air currents produced by the web and moving parts of the machine cause fluttering of the web in these open spaces. The fluttering leads to web breakups at the upstream end of such cylinder arrays, as the strength characteristics of the web are still poor due to a high water content.

Efforts have been made to resolve this problem by using a single-wire run, wherein the open runs of a web are eliminated and the latter travels supported all the time by one and the same dryer wire between cylinders included in two tiers. The drying effect of those single-tier cylinders, whereat the wire at this point lies between the web and the cylinder, is negligible as the wire prevents the transfer of heat from the cylinder to the web. Indeed, in the most recent machines, such cylinders have been replaced with suction or vacuum rolls, and this has resulted in improved machine operating characteristics and the threading ropes have become unnecessa¬ ry.

Originally, the single-wire groups generally used to comprise just two or three upstream drive groups of a machine, but their number has been increased as the machine speeds have increased. Some recent machines lack completely the twin- wire cylinder groups. A drawback in a single-wire run is the increased length of a dryer section, leading to the increased length of a machine ⁴ hall ^j and, thus; to the increased factory building costs. On the other hand, a drawback affecting the paper quality is that, in a single-wire run, heat is always supplied to the web from the same side of paper, resulting in possible defects in paper (curling) .

As a summary of the above alternatives, it can be said that the benefits of a twin-wire run include two-sided drying operation and a short dryer section, but the drawbacks include poorer running characteristics at high machine speeds. The advantages and disadvantages of a single-wire run are essen¬ tially opposite relative to the above.

In addition, e.g. US Patent 3,753,298 discloses a machine configuration, which employs a twin-wire run but in which the web is all the time supported by either one of the dryer wires. This is effected by passing the dryer wires by way of guide rolls mounted between the dryer cylinders in such a manner that, during the passage between a dryer cylinder and a guide roll, the dryer wire always runs tangentially to the other guide roll and the other dryer wire wrapping there- around, whereby the web can be transferred from one dryer wire to another at these points without open draws. A weakness of the solution disclosed in the cited publication is that the run of a web against a dryer wire between dryer cylin¬ ders and wire guide rolls is not secured. Thus, the pressure differences prevailing in pockets defined by dryer cylinders and wire sections, the air currents produced thereby and, on the other hand, the adhesion forces between the web and cylinder surfaces detach the web from the dryer wires. Thus, the open, unsupported web is again susceptible to wrinkling

and, at sufficiently high running speeds, this again leads to web breakups.

Naturally, attempts have been made to improve the operating characteristics of such a machine configuration by providing such multi-cylinder dryers with air current controlling and/or producing' structures' at suitable locations'. This type- of solutions have been disclosed e.g. in Finnish Patents 68279 (Patent Application 841167) and 76142 (Patent Application 854494) . The passage of the web against the dryer wire is secured by using vacuum developing blow boxes. However, the blow box assemblies and nozzle designs proposed in the above references require very large overall air quantities for a desired effect. These air quantities are typically ca. 2000- 2400 m ³ /hm per pocket. In terms of energy efficiency, this is undesired and leads to very large diameters in compensa¬ tion air manifolds as well as highly complicated and expensive air circulation systems.

An object of the invention is to provide a method and a device for effecting the above type of closed twin-wire run with a web supported at all times in a manner that the amount of air can be minimized. In order to achieve this object, a method of the invention is primarily characterized by what is set forth in the characterizing portion of claim 1. An air guiding surface located on the other side of the dryer wire and opposite to the pocket allows to blow air from said nozzle into said pocket effectively and without large amounts of air. On the other hand, a device for carrying out the method is characterized by what is set forth in the characterizing portion of claim 7. Thus, the device includes a guiding surface mounted on the other side of the dryer wire in conjuction with the nozzle and opposite to the pocket for guiding an air current blown from the nozzle through the dryer wire and into the pocket.

The annexed dependent claims 2-6 and 8-12 disclose further preferred embodiments for the method and the device.

The invention will now be described in more detail with reference made to the accompanying drawing, which shows a side view of a multi-cylinder dryer included in a papermachine and provided with a device for utilizing the invention.

As for its general configuration, a multi-cylinder dryer shown in the' drawin ^s is similar to ¹ that disclosed in the above-cited US and Fl Patents. The multi-cylinder dryer comprises cylinders 1 included in a first tier of cylinders and cylinders 2 included in a second tier of cylinders, these being heated cylinders and intended for removing water from a web W to be dried, traveling in close conformity therewith under the guidance of dryer wires. A first dryer wire kl travels in a tortuous path around top cylinders making up the first tier of cylinders, said web W traveling supported by it and being always pressed against the jacket of each cylinder 1. Between the cylinders, the wire is passed around guide rolls hi located below the cylinders, the position of these rolls being such that the loops formed by the wire and the web pass around the rolls obliquely relative to the longitudinal direction of said first tier of cylinders. In a corresponding fashion, said web W is passed around the jackets of cylinders 2, in this case the bottom cylinders, included in the second tier of cylinders, by means of a second dryer wire k2, said wire being passed around guide rolls h2 included in the second tier of cylinders such that the loops formed by the wire at this point are directed obliquely relative to the longitudinal direction of said second tier of cylinders in the same direction as the loops formed by said first dryer wire kl. In order to support web W over the entire distance, the loops formed by different dryer wires are arranged to run tangentially to each other such that over the section, wherein second dryer wire k2 travels from cylinder 2 to guide roll h2, it will run tangen- tially to guide roll hi of first dryer wire kl, whereby the web W extending from the jacket of said cylinder 2 can be

transferred to the loop of wire kl running around guide roll hi for carrying it further to the jacket of first cylinder 1. Since a wire loop located downstream of this cylinder in the web traveling direction runs in turn tangen- tially to guide roll h2 of that wire loop from which the web was transferred, it can be transferred back again to second dryer wire k2 for' carrying it to a ≤ecσnd-tier cylinder 2'. In order to secure the transfer, said wire guide rolls hi and h2 are suction rolls.

The first dryer cylinder 1, a section of first dryer wire kl extending from guide roll hi to this cylinder, as well as a wire section leaving cylinder 1 and located between the cylinder and the guide roll h2 of second dryer wire k2 define together with said second dryer wire k2 a closed pocket tl,2. A corresponding pocket t2,l is formed at said second cylinder 2.

The invention will now be described with reference made to equipment associated with the loop formed by said second dryer wire k2 winding on guide roll h2, but the same applies analogically also to equipment associated with the loop of the first dryer wire kl. These loops include three sections: a section a-c, wherein the wire runs along with web W from the cylinder to the location of wire guide roll, at which the wire is transferred to the dryer wire passing therearound, a section c-d, wherein the wire starting from the transfer point c progresses to the wire guide roll, as well as a section e-f, wherein the wire carrying the web W transferred back travels from guide roll to dryer cylinder.

At the loop formed by second dryer wire k2, along a section a-d between dryer cylinder 2 and guide roll h2. is. mounted, a nozzle s2, located on the opposite side of wire k2 relative to pocket tl,2. The nozzle is intended for blowing air into pocket tl,2 for its ventilation and for securing the stability of web W over the sections of first dryer wire kl defining the pocket, the nozzle having the same basic purpose as the

nozzles disclosed in the above-cited Finnish Patents 68279 and 76142. Downstream in the traveling direction of dryer wire k2 said nozzle s2 is followed by an air guiding surface op, facing a wire section c-d. The air blown from nozzle s2 is guided along this section into a space between wire k2 and surface op, which space will thus be over-pressurized and this plenum zone is indicated"with ^' reference character' pl+. The air guiding surface, which extends roughly parallel to section c-d, covers most of the length of this section, preferably extending to the proximity of the jacket of wire guide roll h2. In the drawing, the surface extends all the way to the gap between the wire and the roll, i.e. it extends beyond a plane tangential to the roll jacket and perpendicu¬ lar to wire k2. Thus, the gap n+ between dryer wire k2 and roll h2 located upstream of point d will also be over-pressu¬ rized. In view of intensifying the gap over-pressure, a sealing t is fitted between the jacket of guide roll h2 and an arched surface hp facing the roll jacket and adjoining the end of air guiding surface op and the roll jacket. The blowing air travels from plenum space pl+, n+ limited by wire k2 into pocket tl,2 through the air-permeable section c-d of dryer wire k2 not covered by web W, taking care of ventilation of the pocket.

The nozzle s2 is located in the traveling direction of dryer wire k2 upstream of point c, at which said web W is transfer¬ red from second dryer wire k2 to first dryer wire kl. The location, at which the plenum zone between the dryer wire and the guiding surface therefore begins, is indicated with reference character b and it is located upstream of point c. In the dryer wire traveling direction, upstream of point a, at which the dryer wire departs from cylinder 2, is located a nozzle si for producing an air blow directed against the wire traveling direction. Thus, between nozzles si and s2 within the section a-b there is provided a vacuum zone pi-. The development of this vacuum is assisted by a surface ap, located between nozzles si and s2 and facing section a-b. The vacuum zone can be used for sucking web W into the contact

with dryer wire k2 over section a-b. Since the vacuum zone terminates upstream of point c, the transfer of web W from one wire to another is facilitated.

The nozzle s2 directed in the traveling direction of second dryer wire k2 has two functions, namely serving as an ejector nozzle for producing a vacuum within a zone- limited directly by section a-b of the wire as well as an over-pressure within section c-d and especially in gap n+ between dryer wire k2 and guide roll h2, for taking care of pocket ventilation as the blowing air finds its way into pocket tl,2.

In practice,, the nozzles si and s2, vacuum surface ap, and air guiding surface op can be simply formed such that said surfaces ap and op are provided by the dryer wire k2 facing side of a common air-blowing box 3 located inside the wire loop, whereby nozzle s2 opens on said side between surfaces ap and op and nozzle si is located at the end of the box upstream of point a, at which the wire and the web depart from dryer cylinder 2.

Within the section e-f, wherein the dryer wire k2 progresses from guide roll h2 to cylinder 2 together with web W received thereon at guide roll h2, there is in turn created another vacuum zone p2- on the other side of the dryer wire relative to pocket t2,l. This vacuum zone is produced by arranging an ejector surface ep inside the dryer wire loop opposite to the wire. Between the ejector surface and the wire within this zone there is induced a vacuum, since the wire has a tendency of grabbing air therealong when traveling at a high speed. In order to intensify the vacuum, said ejector surface ep forms with the wire an angle which can be in the order of 0-15°, opening slightly in the wire traveling direction. The vacuum zone extends in the direction opposite to the wire traveling direction all the way to gap n- between the jacket of guide roll h2 and the wire section e-f. In order to intensify the gap vacuum, the ejector surface ep extends in this direction all the way to the gap, i.e. beyond a plane

tangential to the jacket of guide roll h2 and perpendicular to wire k2, wherein it is joined at point g by the arched surface hp following the jacket of roll h2. As shown in the drawing, the ejector surface ep is constituted of the wire section e-f facing side of the same air-blowing box, which also includes vacuum surface ap and air guiding surface op. The arched' wall', connecting air guiding'surface op"and ejector surface ep and facing the jacket of guide roll h2, is provided with the above-mentioned sealing t which, at the same time, separates gaps n+ and n- as well as the respective plenum and vacuum zones from each other.

Thus, a single air-blowing box located inside the dryer wire loop, by means of a proper design of its sides, can be used for producing both the vacuum zone pi- for securing the adherence of web W to the wire over section a-b, the plenum zone pl+, n+ taking care of the ventilation of pocket tl,2, as well as the vacuum zone p2-, n- for securing the adheren¬ ce of web W to dryer wire k2 or kl upon its transfer from the zone of action of the suction-equipped guide roll h2 or hi at point e to be supported by said wire k2 or kl within section e-f. In addition, it should be appreciated that the plenum zone pl+, n+ for providing the ventilation of pocket tl,2 or t2,l also improves the adherence of web W to the dryer wire within sections which define the corresponding pocket and are located immediately upstream and downstream of dryer cylinder 1 or 2.

The edges of vacuum zones pi- and p2- can be provided with per se known edge blows for preventing the flow of leakage air from the surroundings at the wire edges into the vacuum zone.

The air-blowing box 3 conceivably comprises an air-blowing part 3ab, which receives blow ducts and is provided with nozzles si and s2, as well as an air guiding part 3cf mounted thereon and including air guiding surfaces op and an ejector surface ep as well as surface hp connecting them. Due to the

configuration of a papermaking machine these parts can sometimes be mutually separate parts, which, when positioned successively, provide the above assembly inside the wire loop.

Furthermore, the drawing illustrates how to arrange between the blowing part and the air guiding part a flow regulator, such as a damper plate sp, capable of regulating the amount of air flowing from nozzle s2 through dryer wire k2 into pocket tl,2. The damper plate is located in a flow duct that connects the surface downstream of nozzle s2 with ambient air. When the damper plate is open, some of the amount of air entering in the air-blowing part is allowed to flow out. When the damper plate is closed, all the air flows from the nozzles which are in communication with the air-blowing part. In cross-wire direction, the box can be further provided with a plurality of damper plates that can be adjusted for affecting the distribution of air in lateral direction.