FI84638C - HYBRIDFORMARE FOER EN PAPPERSMASKIN. - Google Patents

Description

84638 Ί Paper Machine Hybrid Fonner

Hybridformare for en pappersmaskin 5

The invention relates to a paper machine hybrid fender comprising a lower wire loop cooperating with a paper machine headbox to form a first single wire, preferably substantially horizontal, dewatering zone in which water is discharged from the web formed. an upper wire loop which, after the first dewatering zone, together with the lower wire run, forms a two-wire second dewatering zone and which former! comprises a first forming roll with a hollow surface arranged inside the upper wire loop, at which said second two-wire dewatering zone starts upwardly curved in a certain sector of this forming roll, a curved cover with the center or centers of curvature on the underside of the loop.

It is known that dewatering of the web formed by the planar wool part of a normal Fourdrinier paper machine takes place exclusively downwards, whereby fines and fillers are removed from the web on the wire side either due to the washing effect of stationary dewatering means e.g. foils or rotating register rollers. It is therefore made of a Fourdrinier machine paperiralna is always anisotropic in respect of its two sides properties, so that the web of the top surface is smoother and contains 30 more fines and fillers, as did the fabric facing surface, which thus is less fines and fillers and which is also seen in the so-called . viiramarkkeeraus. For the reasons set out above, the so-called two-wire formers in which the formation of the web substantially takes place between the two wires so that the unilateralism of the web is at least partially eliminated. Paper made on such machines is therefore preferred over paper made on Fourdrinier machines, especially in terms of printing uniformity.

2,84638 ^ The previously known twin-wire formers which do not use stationary dewatering elements generally have poor formation, since rotary dewatering means cannot produce a dewatering pressure pulsation which is capable of improving the formation. 5 A further disadvantage has been that these known formers have not included the possibility of adjusting the amount of dewatering through the upper and lower wires. In many cases, paper machine users have expressed the wish to make such an adjustment.

10 In the two-wire forming parts of paper machines, various types of so-called dewatering elements are known to be used as stationary dewatering elements. forming shoes, which usually consist of a plurality of strips transverse to the direction of travel of the wire. In addition to the dewatering effect, these strips cause a pulsation in the partially formed ralna between the two wires, as a result of which the fibers of the web move relative to each other so that the fiber agglomerates or flocs in the web disintegrate to some extent. Such forming shoes have a curved guide or sliding surface against the wire and generally have the same structure throughout the length of the shoe. It has also been possible to make such a forming shoe work optimally only in a rather limited speed range of the paper machine and generally only in a certain quality of paper to be produced.

With double-wire formers, a significant portion of the dewatering occurs in the area of the formation-25 shoe. Thus, the forming shoe has considerable potential effects on both dewatering capacity and formation. However, in the past, these opportunities have only been realized to a limited extent. In addition, it should be noted that the forming shoe acts as a guide element for the joint running of the wires, thus contributing to the stability of the running of the wires.

With regard to the state of the art related to the present invention, reference is made to Applicant's FI Patent Application No. 771364 (filed April 28, 1977), which discloses a method of making a multi-ply board and a web-forming unit using a double-shoe forming shoe with an open and closed guide shoe. arranged to be adjustable by filling strips by means of which the slit surface 3 84638 1 of the forming shoe can be converted into a completely closed guide surface. This forming shoe is specifically intended for the production of multilayer board.

Reference is also made to the applicant's FI patent applications 820742 (cf. U.S. Pat.

5,414,566) and 821531, the latter disclosing a forming shoe structure consisting of two or more strip surface portions having different radii of curvature, the mutual lengths of which are adjustable.

10 Recently, modernizations of old fourdrinier machines have become more common, in which one upper wire unit is usually placed on top of the flat wire section, in cooperation with it, in the area of which dewatering can also take place upwards. The aim is both to increase the dewatering capacity and to improve the retention.

15 Such wire sections are called hybrid formers. Even completely new wire sections of a paper machine can be designed from the beginning to be of the hybrid type.

Increasing the dewatering capacity generally allows the speed of the paper machine 20 to be increased, or at least while maintaining the speed, allows the consistency of the pulp fed from the headboard to be reduced, which in itself has beneficial effects. In some cases, the old slow newsprint machines at the above-above-speed units have been modernized into cardboard machines without increasing the speed of the machine.

25

It is a particular object of the present invention to provide a dewatering arrangement for use in hybrid formers that provides improved web formation. Another specific purpose of this dewatering arrangement is to adjust the dewatering event so that it can affect the filler and fines distribution of the web.

It is a particular object of the invention to provide a dewatering arrangement for use in hybrid formers which provides better support and flow stability for wires in a two-wire dewatering zone. The aim is to improve the formation of 4 84638 ^ and to reduce the web streaking caused by the creasing due to the unstable course of the wires.

It is a particular object of the present invention to provide a dewatering member and arrangement for use with a two-wire portion of a hybrid former that allows the paper machine wire portion to be adjusted to operate optimally at both dewatering capacity and web formation at different paper machine speeds and grades.

10

With regard to the theory of dewatering in a two-wire curved formation zone, reference is made to the following publications: Papper och Trä 1972, No. 4, p. 137-146, Jouni Koskimies, Jorma Perkinen, Heikki Puolakka, Eero Schulz, Björn Wahlström: "A Drainage Model for the Forming 15 Zone of a Two-wire Former" and Pulp and Paper Magazine of Canada, vol. 74, no. 2 / February 1973, ss. 72-77, E.G. Hauptmann and J. Mardon: "The Hydrodynamics of Curved Wire Formers."

The hybrid former according to the invention is mainly characterized in that the two-wire dewatering zone between said first forming roll and said forming shoe is provided with deflector units within both the lower wire loop and the upper wire loop. followed by a molding roll, in a particular sector of which the two-wire zone curves downwards or upwards.

In the following, the invention will be described in detail with reference to an example of the application of the invention shown in the figures of the accompanying drawing, to the details of which the invention is in no way narrowly limited.

Figure 1 shows a schematic side view of a hybrid former implemented in the modernization of an existing flat wire section and in which the dewatering arrangement according to the invention is applied.

Fig. 2 shows a second embodiment of the invention in accordance with Fig. 1, but more schematically.

Fig. 3 shows an overview of the main parts of the dewatering arrangement 5 according to the invention and the arrangement in the two-wire second dewatering zone of the hybrid former according to Fig. 1.

Figure 4 shows in more detail the deflector part of the web forming and dewatering arrangement according to Figure 3.

10

As shown in Figures 1 and 2, the flat wire section of the Fourdrinier paper machine is provided with an upper wire unit 50 and thus converted into a hybrid former. The wire plane of the original Fourdrinier section is denoted by the reference T-T. The hybrid former comprises the body 95 of the old wire section, the planar boxes 16 included in the original wire section 15, the wire suction roller 17 and the drawing roller 18, and the guide rollers 19 guiding the downstream of the wire 10.

When applying the invention to the hybrid formers according to the figures, a lower deflector unit 100 is arranged on the outside of the wire part on a supported or old body part 95 according to the present invention.

The upper wire unit 50 comprises a body part 45 shown in Fig. 1, to which various parts, including the upper deflector unit 110, are attached. The passage of the upper wire loop 20 is controlled from the beginning of the two-wire section preferably by a first forming roll 21 with an on-surface 21 ', then dewatering elements 100 and 110 according to the invention and a first revolving roller 22 inside the upper wire loop 20. 10 to original level TT. The two-wire dewatering zone terminates before the upstream 20 pull roller 23. The guide rollers above the upper wire 20 are denoted by reference numeral 24. The rollers 22, 23 and 24 are provided with scrapers 31. The roller 21 also has cleaning devices (not shown) and water collection devices known per se.

The resulting hybrid former has, prior to its double-wire portion, a single-wire first dewatering zone 10a formed by the original flat wire, where the dewatering preferably takes place by dewatering members of the original flat wire section, such as a chest table and foil strips (not shown). In the first dewatering zone 10a, the dewatering takes place downwards through the lower wire 10, but preferably comparatively carefully so that the possibilities for sufficient retention 5 are maintained and that a sufficient proportion of the upward dewatering remains to achieve good formation.

After the trajectory line C of the forming members 100, 110, 14, 15 follows a downward straight common run of the wires 10 and 20 up to the roll 22, whereby the common run of the wires 10 and 20 is directed gently upwards, finally joining the original plane T-T of the down wire 10.

From the lower wire 10, the web W is detached at an oblique run between the rolls 17,18 by the action of the suction zone 40 of the pick-up roll 40 and is transferred to a pick-up fabric 41 which further transfers the web W to the press section (not shown).

The different structural features of Figures 1 and 2 will be described below. According to Fig. 1, after the deflector units 100 and 110 20, a forming shoe 14 with a strip cover 14a follows, in the region of which the common run of the wires 10 and 20 runs upwards all the time with a relatively large radius of curvature R of the order R 2.5-5 m.

Further, according to Fig. 1, a very short straight run of the wires 10,20 follows the curved strip shoe 14a of the forming shoe 14, followed by a forming roll 15, in which sector b the common run of the wires 10 and 20 turns downwards. This is followed by the above-mentioned smooth-surfaced roll 22 inside the loop of the wire 20, in which sector c the common run of the wires turns and joins the plane T-T of the lower wire 10. Figure 1 shows a dewatering trough with a bottom edge 30 of the bottom plane close to sector b of the roll 15. The dewatering tray 36 is attached to the frame 45 by horizontal shafts 37 and can be turned by a screw gear 37 via arms 38. By means of the dewatering trough 36, the water discharged through the upper wire 20 is led to the side of the paper machine. The surface of the water in the trough 36 is marked with S.

The hybrid former shown in Figure 2 differs from that described above for the two-wire dewatering zone after the deflector units 100 and 110. According to Fig. 2, after the deflector units 100 and 110, the flow of the wires 10,20 is substantially straight and in the region of these it curves into a suction source 13 under the curved strip cover 14a of the forming shoe 14 connected to the suction foot. Said sloping run 5 is so steep or so long that the two-wire dewatering zone extends in the sector c of the roll 22 below the plane T-T by a height difference. This arrangement makes room in Figure 2, the specific vedenpoistokaukalolle 28, which comprises a made-up of the wires 10 and 20, oblique run vicinity of the walls 26 and 27, between which 10 of the upper wire 20 through the water leaving thrown from the kinetic energy of the impact direction of arrow F and exits from this and the difference in height between the air that it is necessary to use any special suction devices such as the known AUTO-SLICE ^ ™ ^ devices. This simplifies and degrades the structure. According to Fig. 2, in sector c of roll 22, the common run 15 of wires 10,20 turns upwards and gently into an oblique run, followed by a guide roll 16a, in which sector the two-wire 10.20 forming zone coincides with plane TT of lower wire 10 and 20 differs from the web W following the lower wire 10.

The combination of the invention essentially comprises deflector units 100 and 110 which control the common flow of the wires 10 and 20 upwards from the sector a of the forming roll 21 up to the inlet edge of the strip cover 14a of the forming shoe 14.

Figures 3 and 4 show in more detail the embodiment of Figure 1, and according to Figures 3 and 4 there is a deflector unit 100 inside the loop of the lower wire 10, comprising successive deflectors 101, 102 and 103 at a distance K1, the first 101 of which is close to sector a of the forming roll 21 ( at a distance Kq) and the last 103 near the first strip 14aj of the forming shoe 14 (Fig. 4). Correspondingly, inside the upper wire loop there is a deflector unit 110 comprising two successive deflectors 111 and 112, the planar end faces of which face the inner surface of the upper wire 20.

The lower deflector unit 100 is preferably fixed, but its deflectors 101, 102 and 103 can also be arranged in guides 105 or the like to be moved mainly in the direction of travel of the wires 10 and 20. The upper deflector unit 110 is arranged to be adjustable either in its entirety or separately in the direction of arrows A, i.e. in a direction perpendicular to the plane of the wires 10 and 20, so that the end faces of the deflectors 111 and 112 guide the wires running together with the deflectors 5 and 102 of the unit 100. so as to obtain a direct or very low wave height wavy joint run of the wires 10,20, which produces strong impulses on the web W on both sides thereof. As a result of these impulses, the formation of the web W improves. By adjusting the position of the overhead deflectors 111 and 112 in the direction A, the magnitude of said pulses 10 can be adjusted to optimize the quality of the paper to be produced, the speed of the machine and other conditions. Instead of adjusting the position of the entire upper deflector unit 110, the deflectors 111 and 112 can be attached to a body portion provided with guides 113,114 in connection with the body portion of the defector unit 110 for adjustment in the direction of arrows A15. Thus, if necessary, the first and second overhead deflectors 111 and 112 can be adjusted independently of each other. In some applications, the lower deflectors 101, 102 and / or 103 can also be arranged to be positioned in a position opposite to the plane of the wires 10 and 20.

20

The distance between the upper deflectors 111 and 112 is denoted by K 1. Correspondingly, the distance between the lower deflectors 101, 102 and 103 is marked Karila and e.g. Κο ^ · ^ “150 ... 300 mm, preferably Kq = 200 ... 250 mm.

25

The end face lengths of the upper deflectors 111, 112 are denoted by Lili, and the corresponding end face lengths of the lower deflectors 101,102,103, respectively, are denoted by L1, generally = 10 ... 40 mm, preferably = 20 ... 30 mm.

30

The blade or deflector angle of the overhead deflectors 111, 112 is denoted by α, and e.g. the angle α 2 * 15 ° ... 40 °, preferably α 2 * 20 ° ... 25 °. The deflector angles 101, 102 and 103 of the lower deflectors, respectively, are denoted by a2. It is generally preferred that α ^ <α ^, and an = 30 ° ... 60 °, suitable for α-β5 λ ** 40 ° ... 45 °. The angles α1 of the different deflectors 111 and 112 may be of different magnitudes. Accordingly, the angles α1 of the different deflectors 101,102,103 may be somewhat different from each other.

The position of the deflectors is preferably such that the steel edge of the deflectors 111 and 112 inside the upper wire loop 20 is in the middle of the deflectors 101,102,103 inside the lower wire 10. The planes of the end faces of the deflectors are substantially in the same plane as the tangent plane 5 flanking the surface of the forming roll 21 on the one hand and the first strip 14a ^ of the forming shoe 14 on the other hand. The end faces of the deflectors may also be at a small distance from the inner surfaces of the wires 10 and 20 to avoid wear. The deflector strips are preferably made of ceramic material or other similar wear-resistant material.

10

The following are the results of the comparisons obtained during the test runs on the applicant's test paper machine. The following table shows the first row lip opening (mm), the second row the Beta formation with the former geometry of Figure 1 without deflector units 100 and 110 and the third row the corresponding Beta formation readings using the deflectors fitted and dimensioned according to Figure 4.

TABLE

20

Lip opening (mm) 12 14 16 std. shoe 3.50 3.28 25 defl. + std. shoe 3.16 2.94 3.03

The following claims set forth within the scope of the inventive idea defined by the various details of the invention may vary and differ from those set forth above by way of example only.

35

Claims (9)

A paper machine hybrid former comprising a lower wire coil (10) in cooperation with the paper machine inlet coil, which lower wire coil 5 forms a first dewatering zone (10a) of single wire, which is most preferably substantially horizontal, at which zone one removes water from the web ( W) formed by dewatering means inside the wire loop through the lower wire (10), and an Upper wire unit (50), where there is an upper wire loop (20) guided by guide and web forming rollers (21,22,23,24) , Which (20) after the first dewatering zone together with the course of the lower wire (10) forms a second double wire dewatering zone and which former comprises a first forming roller (21) arranged inside the upper wire coil (20) and which is provided with an excavated surface (21 '), at which (A) forming roller said second double-wire dewatering zone begins, which zone curves up at a given sector (a) of this forming roller (21), and a forming shoe (14) which disposed within the lower wire loop (10) which guides said second dewatering zone after said forming roller (21), said forming shoe having a curved lid (14a) guiding the lower wire loop (10), the bending center or 20 centers of the lid being ρά the lower The side of the winding loop (10), characterized in that, at said double winding dewatering zone between said first forming roller (21) and said forming shoe (14), deflector units (100,110) are arranged inside the lower winding loop (10) and the upper the winding loop (20), with which units sufficiently strong formation-enhancing impulses acting on both sides of the web (W) are formed, and following the curved molding lid (14a) of said forming roll (14) follows a forming roll (15); 22), wherein the double-wire zone at a given sector (b; c) of the forming roller (15; 22) curves downwardly (Figs. 1) or upAt (Fig. 2). 30 Molding according to claim 1, characterized in that at the area of the molding lid (14a) said forming shoe (14) curves down the common course of the wire (10,20) and runs to the forming roller (22) inside the upper wire loop (20). , whose bottom position (22) is located below the (Hi) plane (TT) as determined by the initial portion (10a) of single wire. ia 84638 3. Molding according to claim 2, characterized in that, after said forming roller (22), an upwardly inclined course continues which extends all the way to the articulated roller (16a) within the lower wire loop (10), within whose area (B) the molding cone with double wire most conveniently ends 5 (Fig. 2). Molding according to Claim 1, characterized in that the downwardly inclined common course of the wire (10, 20) follows the molding roll (15) with the most suitable screen surface, which race curves upwardly at a given sector (c) of the molding. - or the guide roller (22), thereby coinciding with the plane (TT) of the starting portion (10) with single wire of the lower wire (10) (Fig. 1). Molding according to any of claims 1-4, characterized in that the molding lid (14a) of said molding shoe (14) is cleaned with a suction source (13). Molding according to any one of claims 1-5, characterized in that in each of the deflector units (100,110) there are at least two deflector strips (101,102,103,111,112), whose planar front surfaces lie against the inner surface of the wire (10,20 ) and substantially in the common tooth plane, which is intended to form the forming roller (21) which precedes the deflector units (100,110) and the first molding strip (14a ^) of the molding lid (14a) of the forming shoe (14). 25 Molding according to any one of claims 1-6, characterized in that the positions of the deflector strips (101,102,103,111,112) of both or one of the deflector units (100,110) can be controlled at least perpendicular to the plane of the wires (10,20) at these. a direction (A) for controlling the magnitude of the impulses directed at the male (V) according to the quality of the paper to be produced, the machine speed and other corresponding parameters. Molding according to claim 7, characterized in that the lower deflector unit (100) is stationary and that the position of the upper deflector unit (110) or a deflector therein or most suitably all deflectors therein (111,112) can be controlled, most preferably at right angles. reference (A) in relation to the plane of the wires (10.20). i5 84638 Molding according to any of claims 1-8, characterized in that between the first forming roll (21) and forming shoe (14) there is a double-wire dewatering zone running upwards obliquely and substantially straight. 5 10 15 20 25 30 35