FI61331C - ANORDNING FOER S K SPETSDRAGNING VID PAPPERSMASKINER - Google Patents

Description

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Patent · och registerstyrslsen Ammua uthgd och utl. »Krtft * n publicurad 31.03.82 (32) (33) (31) Pyydetty« cuoikuut-i «| W prtartMC 18.08.75

Sweden-Sweden (SE) 7509205-6 (71) (72) Sidney C. Rooney, 5615 College Highroad, Vancouver B.C., V6T I H I,

Canada (CA) (74) Leitzinger Oy (54) Device for so-called tip pulling in paper machines - Anordning för s.k. The present invention relates to paper machines, more particularly to a device for so-called tip pulling in such machines, the term referring to a measure performed during machine start-up or shut-down to guide a new paper web from the drying cylinders of the machine to the calender rolls. To thread the web between the rollers, "pull the tip", i.e. the very wide paper web is divided longitudinally along the other edge by separating the narrow strip and this is guided between the rollers by hand or by means of compressed air jets, after which the strip continues to move through the machine and expands, i.e. spreads to cover the whole paper web!

Modern paper machines operate at very high speeds and often the paper web plunges through the machine at a speed of the order of 1000 m / min. If the paper web breaks at full speed, it becomes a difficult problem with the accompanying waste of time to resume operation. As mentioned above, the tip of the paper web is pulled at the point of breakage and re-threaded between the rollers, noting that manual handling can be very dangerous for personnel and controlling the tip with a jet of air is cumbersome and difficult to control due to flaking.

U.S. Pat. No. 2,631,331 3,355,349 proposes a mechanical-pneumatic auxiliary device for restoring a paper web after rupture, so that an auxiliary device or a series of such devices can restore the paper web in place at full speed, i.e. the machine speed does not have to be slowed down after the paper web breaks. the tip of the web plunging at the breaking point is pulled and the auxiliary device or devices continue to guide the tip, i.e. the strip, at the normal running speed. The tip then widens as usual to the full width of the web.

The device according to said US patent consists of a sealed unit, which essentially comprises a rather narrow conveyor belt running between two rollers. The rollers are supported at each end by a vacuum box, which is thus between the runs of the conveyor belt. The vacuum box or suction box forms the body of the device and supports an electric motor which uses a conveyor belt via wedge belts. This is made of a reticulated material with wide loops and one run of which extends very close to the other side of the suction box provided with openings or slits. In this way, air can be absorbed down through the conveyor belt into the suction box and the tip of the paper web can then be made to grip the conveyor belt to follow this, which is used at the normal speed of the paper web. In order to hold the tip of the paper, i.e. the strip, securely on the hose near this receiving end, a press roll is arranged, which can be turned down against the conveyor belt by means of a pneumatic drive and press the paper tip captured by said suction against the belt. The entire device is movable and adjustable so that the stroke of the belt carrying the paper tip can be directed to the nip between the rolls of two successive calenders. At the end of the belt run, a small compressed air nozzle is arranged under the belt, by means of which the paper tip can be blown off the belt, whereby the tip will continue to travel directly in the direction of the belt travel, i.e. Preferably, the entire set of such auxiliary devices is arranged between the rolling chairs of the paper machine so that the tip of the paper can be moved from one rolling mill to another and guided through the machine in the correct manner. When the auxiliary device has guided its strip correctly, the suction is stopped, the pressure roller is raised and the whole device is turned to the inoperative position. Gradually, the paper tip then spreads to the full width of the paper web.

The auxiliary device briefly described above (for a more detailed description, reference is made to the said U.S. patent) has been found to have a few serious drawbacks in practice 61331. First, the press roll fitted to the inlet portion of the belt tip conveying paper tip is difficult to handle and enters the “path” of the incoming paper tip, and second, the perforated conveyor belt has proven weak and difficult to withstand, especially at existing joints.

It is an object of the present invention to provide a new and improved tip pulling device of the quality in question for paper machines. This object is achieved and the above-mentioned drawbacks associated with the previous tip pulling devices are eliminated by a device according to the invention having the features set forth in claim 1.

The invention will now be explained in more detail by way of example with reference to the accompanying drawings, in which:

Figures 1 and 2 schematically show a side and top view of a tip pulling device according to the invention, respectively.

Fig. 33 is a perspective view of the device mounted on a workstation near the two calender rolls of a paper machine.

Figure 4 is a schematic side view of a part of a paper machine and illustrates how three auxiliary devices according to the invention can be installed to guide a paper tip between two calender roll chairs.

Figure 5 shows the way of dividing the suction slots on the surface of the suction box and the curve for the vacuum which is developed in the suction box in its longitudinal direction.

Figure 6 shows schematically how, according to the invention, a conveyor belt can be made of a single endless continuous yarn or rope.

Figures 1 and 2 schematically illustrate a tip pulling device according to the invention, i.e. a gripping device, which is indicated in its entirety by reference numeral 10. The device comprises a suction box 12 in which a vacuum is maintained via a vacuum line 14 and which forms the body of the device. The box is suspended in place on the paper machine by means of fastening members (not shown), for example as shown in Fig. 3 and will be explained below. At both opposite ends of the suction box, conveyor belt rollers 16 and 18 are mounted by means of respective lugs 17 and 19 attached to the suction box. An endless belt 20 passes over the rollers, which according to the introduction is perforated and which has, for example, a net belt with rather large loops, so that air can flow through it without greater resistance. The suction box 12 also forms a bracket for a small motor stand 22 supporting an electric motor 24 with a power of 1a and 2 hp, which uses a belt pulley 16 and thus a belt 20 via a V-belt drive 26. According to Figure 1, the against which the direction of movement of the belt is indicated by an arrow. According to Figure 1, a small compressed air nozzle 28 is arranged at the right end of the suction box 12, i.e. in the direction of movement in the vicinity of the upstream end, which here directs a few jets of air upwards through the belt, as shown in Figure 1.

When the gripping device is operating, the electric motor 24 drives the belt at a speed corresponding to the web speed of the paper machine for which the device is intended. The vacuum line 14 removes air from the suction box 12, which at its upper side, immediately below the upper run of the belt 20, is provided with slots or openings through which air is absorbed into the box, whereby air must thus pass through the perforated belt. The dotted line 30 indicates a strip of paper, i.e. the "tip" mentioned in the introduction, which differs from the paper web, for example when it breaks. Air enters the strip into the left part of the suction box and thus secures it against the conveyor belt, following along this suction box to detach it at the right end of the suction box from the jets of air coming from the nozzle 28. Due to its own kinetic energy, the strip continues to travel straight ahead and since the device is adjustable and orientable as mentioned above, the strip can be guided to the desired location as illustrated in Figure 3. Here the device 10 is arranged next to the paper machine between two calender rolls. the device is in a position opposite to the position shown in Fig. 1, i.e. the effective running of the conveyor belt 20 is turned down and is just above the incoming paper web, while the drive motor 24 is thus in this position above the device. When the paper web breaks, the "tip" is pulled in a known manner at the same time as the gripping device 10 is started. The tip, i.e. the strip, is caught and gripped against the conveyor belt on the lower right side of the device, quickly guided out and spun away from the right end of the belt, the device being oriented so that the strip meets the nip between the rollers and is fed between them. In this case, the device is rendered inoperative and detaches a strip which, after the stabilization of the state, expands, as indicated by the dotted line 30 'in Fig. 3, to cover the entire web, so that the normal operating state is restored for these rolls.

Figure 4 schematically illustrates how a plurality of gripping devices according to the invention can be adapted to work together to guide a paper tip over large distances, for example between two roller chairs belonging to a calender. A thick solid line 40 marks either a paper web passing certain rollers in the first roller chair 42 for subsequent upward passage through intermediate rollers 44 and 46 to a second roller chair 48, where a web enters between the top rollers of the chair. Three tip pulling devices according to the invention, i.e. gripping devices 50, 52 and 54, are arranged between the roller chairs, whereby all the devices are in principle similar and differ from each other only in the length of their conveying path. It is now assumed that the paper web passes between the roller chairs. Without changing the speed of the machine, all the devices 50, 52 and 54 are made to operate simultaneously as the tip is pulled in the paper web coming from the first roller chair 42, while the remaining part of the web is allowed to go down to the floor collection chamber under the machine. The dotted line 40 'now marks the passage of the tip from the roller chair 42 to the roller chair 48. While the strip leaves the first roller chair, it is gripped by a right gripper 50 which pushes the strip to the inlet end of to be transported further downwards between the rollers in the chair. At the same time, these three gripping devices then allow the strip to pass over the intermediate rollers 44 and 46 and the paper web can now gradually regain its full width.

As can be seen from the above description, provided that the gripping device according to the invention can be gripped, held and conveyed by the tip of the paper without the aid of another holder, such as an adjustable roller, present in the previously known gripping device mentioned in the introduction. According to the invention, it has proved possible to safely grasp and hold the tip of the paper without any means other than suction of the suction box, if the box is made so that the air inflow into the box is concentrated at the inlet against a conveyor belt running on top of the suction box. Figure 5 schematically illustrates a way to achieve this variable suction effect. Reference numeral 61331 denotes an elongate, substantially angular top side of the suction box, i.e. a suction side, which is then placed tightly below the effective run of the conveyor belt. The top side 60 is provided with a plurality of in-flow slits or perforations 62 extending transversely to the longitudinal direction of the box. The various slits or perforations are equal but unevenly distributed along the length of the box, more specifically so that on the inlet side of the box, i.e. in the part of the box below the receiving part of the conveyor belt, the slits are dense while less common towards the opposite end of the box. An air tension is then created between the top side of the box and the perforated conveyor belt just above it, which is stronger on the inlet side of the box than on its outlet side, and when the paper tip strikes it, a correspondingly higher vacuum is created on the inlet side. In Fig. 5, the pressure i between the upper side of the suction box and the conveyor belt above which the paper tip υη is marked is denoted by p, which develops into a strong vacuum in the area where the paper tip meets the gripping device. This high vacuum is naturally achieved at the expense of the remaining length of the web, but it has been shown that for safe and stable use it is sufficient that the tip of the paper is struck hard against the conveyor, while still having sufficient moderate suction and under vacuum.

It has already been found in practice to be appropriate to increase the vacuum towards the end of the track, i.e. that there again the cracks are placed more frequently, so do you? the tip of the paper adheres very tightly before it is affected by the previously mentioned compressed air jets which blow the tip off the path. In this case, it has been found possible to improve the "aiming" with the device according to the invention, i.e. the paper strip can be moved in its path along a more precise, straighter path than otherwise. In practice, it has been found that with the device according to the invention it is even possible to push the strip directly through an opening in a thickness gauge which is arranged at a suitable place in the paper machine for measuring the thickness of the web. As for the fact that the opening is narrow and has a certain longitudinal dimension, such an application of the device is relevant.

Regarding similar, but differently divided, ..trapart! the arrangement shown in Figure 5 of the suction slots or perforations 62 with respect to the longitudinal direction of the suction box. It should be noted that this arrangement is only an example and that the same effect can be achieved in other ways. Thus, for example, the piercings may have approximately the same division, but may be of different sizes or may have both different sizes and divisions. They can also be oriented parallel to the longitudinal direction of the suction box and be offset from each other so as to satisfy the condition of different inflows.

It is also possible, especially in the latter case, to make the slits so that the maximum inflow at the inlet end of the suction box in turn has a maximum in the middle of the suction side as seen perpendicular to the longitudinal direction of the box.

The previous difficulties discussed in the introduction are to make a perforated, fast-moving conveyor belt durable, especially at the belt ends and joints. In order to provide a stronger conveyor belt, it has been proposed to assemble the belt from a large number of slides adjacent to each other with endless ring-closing ropes located in their own grooves in the conveyor folding rollers. Thus, the conveyor belt will consist of a large number of closely adjacent strands or yarns, with air passing through the belt through the spaces formed between the strands. The advantage of such a structure is, of course, that it is quite easy to produce strong and durable endless tires of this quality, but the proposal has not proved practical. First, due to the fact that the strands or yarns used at high speed will not remain stable laterally, but will oscillate and oscillate back and forth due to the difficulty of maintaining a sufficiently large and uniform tension in the different yarns separated from each other. However, these drawbacks can be alleviated and provided by a stably running "wire rope" as schematically shown in Figure 6. In this case, the belt is not assembled from a series of separate, completely closed rings * but from a single long length wire or rope 64 running back and forth between two rollers 66 and 68 with grooves for the rope. For the sake of clarity, Figure 6 shows only (in solid lines) those parts of the reciprocating yarns which form the upper runs of the yarns. The wire or rope is now wound so that it starts at the grooves of the second end or end of the first two folding rollers at approximately the center of each other, wound with a small screw rise from one roll to the last grooves of the opposite ends of the rolls. Here, the wire 64 is now returned - and here the passage is indicated by a dotted line in Fig. 6 - via the guide rollers 70 and 72 to the opposite ends of the guide rollers 66 and 68 to fit into the output grooves at these ends of the rollers. In this way, the conveying path is formed by a single endless wire or rope running continuously around the folds. It follows from the nature of the structure that the tension in the loops formed by the wire becomes equal and the conveying path remains flat and uniform. With regard to the arrangement according to Fig. 6, it is emphasized that within the scope of the invention it is possible to assemble a conveyor track from a limited number, for example two or three tracks forming a single wire or rope arranged side by side.

Claims (3)

9 61331 A device for so-called tip pulling in paper machines, comprising a strip (30) detached from the paper web of the machine gripping and guiding between rollers of the machine, which device (10) is adjustable in position and direction and which comprises a vacuum or suction box (12) has an effective suction side (60) with air intakes (62) and at its ends having folding rollers (16, 18) for the endless conveyor belt (20) driven by the drive motor (24), so mounted that the second run of the belt (20) becomes extend tightly close to said suction side, the conveyor belt being made perforated or permeable, so that the air drawn in through the suction openings (62) can pass through the passing belt (20) and thus attract said paper web-separated strip (30) and place it against the belt; to follow the belt, characterized in that the suction openings (62) below the conveyor belt (20) are formed and arranged so as to facilitate the inflow of air u and becomes strong at the inlet end of the belt, ie. where the belt runs in the suction box (12) on the suction side (60) above, deliberately to react quickly to this end, and with a strong vacuum hold on the strip (30). 2. The apparatus of claim 1, characterized in that below the conveyor belt (20) suction openings (62) is configured and positioned so that the air flow also increases the belt towards the outlet end, ie. Where the belt leaves the suction box (12) on the suction side (60); however, not to the same level as at the inlet end of the belt. Device according to one of the preceding claims, characterized in that the air inflow openings have a plurality of perforations or slots (62) substantially perpendicular to the longitudinal direction of the suction box (12), differently distributed over the length of the box according to the desired distribution of air inflow.