SE509288C2 - Pick-up system for web in the press section of a paper machine - Google Patents

Abstract

7. This web transfer unit has the following component: elastic endless belt 55, pressure rolls 50 and 56 which press said belt 55 against hard roll 8a by way of the web, belt drive roll 55 to propel belt 55, tension roll 53 to supply said belt 55 tension, belt guide roll 54, and the pressure device to press rolls 50 and 56 on hard roll 8a. The web transfer system generates the necessary level of draw to doff the web paper by utilizing the deformation of the elastic endless belt 55, described above, which develops when it is pressed against hard roll 8 a, although open draw is at zero.

Description

509 288 2 either of the paper roll 15 and the initial felt roll 17 are moved to the position indicated by a dashed line, as shown at 15 'and 17' in Fig. 8, to ensure sufficient space for the tail to easily pass thereby blowing air from the air nozzle of the carrier jet 19, removing the tail from the press center roller 8a, placing it on the felt 21 for transport to the next process step, as shown at 2 ".

Fig. 10 describes the operations when web 2 is moved from the conventional one 8a to the subsequent, fourth press felt 21. In Fig. 10, the web is dehydrated by 3P, the felt 9 is pressed hard against the side of the press center roller 8a due to the dehydration, or for to be more precise, attach to it. The web attached to the press center roller must be removed before it is transferred to the subsequent press and consequently the subsequent press step is driven faster than the previous process.

This additional speed is called "pull" ¿This pull creates tensile stress in the web, the force of which pulls the web off the press center roller, as opposed to adhesion. A tensile force proportional to the tensile acts on the entire width of the open tensile part (part of the fabric not supported by felt or roller). This tension stretches the path. The part of the web that is elongated lies primarily on the area to be peeled off, the place where the tensile force grows, but the elongation varies from part to part, depending on the uneven quantity of fiber, the dispersion and the additive distribution, which gives an uneven stress. If the track is partially destroyed, it breaks off across the entire width. The extent of the partially focused elongation increases relative to the length of the open stroke, which increases the risk of paper breakage. It is therefore necessary to shorten the open draw section as much as possible. An example of such measures taken is illustrated in Fig. 11. The press center roller 8a and the suction roller are laid out to make it possible to make the open traction portion as short as possible and to limit it to only one place.

In Fig. 11, if the suction roller is pressed against the press center roller 8a in order to bring it against the open draw to prevent paper breakage, it is found that the felt and what is transported are wound around the suction roller at the same speed as the press center roller. However, no traction is achieved, so the traction force on the web is insufficient to peel it from the center roll. The negative pressure of the suction roller 509 288 acts to peel off the paper only after pinching due to insufficient ventilation of the press center.

As a result, it is impossible to peel the web from the press center roll alone with the negative pressure of the suction roll, so the web is left adhering firmly to the press center roll due to its adhesion. In order to pull the web from the press center roller, there must therefore be a pull and there is no alternative but to maintain the minimum open pull. After all, the need remains to find a fundamental solution to the previously mentioned issue of paper crime.

Paper machines have become considerably faster in recent years; Some ordinary newsprint machines operate at a speed of close to 1300 m / min and there is an increasing need for operations involving 1500 m / min. An obstacle to the faster operations of paper machines is the question of transferring the web from one press to another and from the press section to the dryer.

In other words, the method previously used was to peel off the tail of the web with the air nozzle as described above before transitioning to the next process. In faster operations, however, the web becomes more difficult to peel off from the press center roller. In order to remove the web from the press center in a stable manner, it is necessary to create a larger draft between the presses or the press and the dryer. After the press portion, however, the web has a moisture content of 40-45% and its strength is very low compared to dry paper and the web is not supported with felt or anything else while in the above portions. Depending on the so-called open the pull, the paper has a tendency to break if the pull becomes larger. Even if paper is passed through the entire system and normal operations are started, the paper is easily broken by fluctuations. OBJECTS AND SUMMARY OF THE INVENTION The present invention is designed to solve the above problems, by the features set forth in claim 1. Further extensions and embodiments of the invention appear from the subclaims.

An elastic band was used to tear off the web from the hard roll (center roll of the press or top roll); the thinning of the strip which occurs when pressed against the hard roll is used to expand the surface of said strip at this edge and create a gap between the web and the hard roll. To peel the web from the hard roll to the belt side or transfer the web adhering to the belt to the next blanket or canvas, folds or small openings are created in the circumferential direction in advance on the belt surface, the vacuum box covered by the next batch of blanket or canvas is pressed against the web and the web is transferred to the next step blanket or canvas using air pressure passing through the web.

Accordingly, the present invention has the following features: In the removal device mounted on the press of the paper machine, the side in contact with the web is elastic while the other side has an endless belt made of a less elastic material and also a hard roll, placed opposite said strip. The belt is pressed against the hard roll by means of the web so that the belt can be deformed to remove the web from the hard roll and guide it on said belt.

In the case of the present invention, the surface of the elastic band which meets the web moves during the time it remains applied to the web. The surface of said elastic band moves as fast as the web or faster and moves at an increasing high speed, especially since the elastic band is no longer subject to deformation at and after the point of maximum pressure, with the consequence that sufficient tensile stress is generated with an open pull equal to zero to pull the web from the center roll of the press.

Brief Description of the Drawings Fig. 1 is a side view of the removal system used in the first example where the invention is put into practice.

Fig. 2 is an explanatory drawing describing the movement of the web from the hard roll (center roll of the press) in Fig. 1 to the belt.

Fig. 3 is an explanatory drawing describing the movement of the web from the hard roll of the present invention to the belt.

Fig. 4 is an explanatory drawing describing the transfer 509 288 of the web from said belt to the next blanket.

Fig. 5 is a cross-sectional view of the operations of transferring the web from said belt to the next blanket.

Fig. 6 is a cross-sectional view showing other examples of the structure of the belt when the web is led from the same belt to the next blanket.

Fig. 7 is a profile of the removal system involved in the second example, showing how the invention was used.

Fig. 8 is a side view of the conventional paper transport operations.

Fig. 9 shows a side view showing the relationship between the web and the press unit in the conventional press section.

Fig. 10 shows a profile of the conventional paper feeding mechanism.

Fig. 11 shows a profile of the conventional paper feeding mechanism.

Detailed Description of Preferred Embodiments The removal device in the press section of the paper machine included in the present invention is described below with the aid of the accompanying drawings.

Figures 1-7 illustrate examples in which the invention is realized. Fig. 1 shows an example using the removal device according to the invention in the press section of the paper machine from the third press (3P) to the fourth press (4P). In Fig. 1, the web produced in the wire portion is sucked up and adhered to the receiving felt by means of a negative pressure acting on the suction receiving roll 3 and then transferred, deposited on the center roll 8a of the press, to the hard roll following the third press (3P). So far, the process does not differ from previous systems. The take-off system, which carries the web 2 from the center roll 8a of the press to the next process, is composed of the following elements: an elastic endless belt 55, pressure rollers 50 and 56 for applying said belt to the center roll 8a of the press via the web, belt drive roller 52 for moving said belt. tension roller 53 to provide tension in said belt, belt guide roller 54 and a pressure device, not shown, for pressing the pressure rollers 50 and 56 against the center roller 8a of the press. In the above device it is also possible to place the pressure roller 56 in a place where the belt touches the center roller 8a and thereby prevents the elastic band from thinning.

In the following, the operations in which the web is separated from the press center 8a are explained in the above device. In Fig. 2, where the elastic band 55 with a less elastic core 56 is placed in a position t2 far from the surface which is in contact with the web, to be pressed against the center roll 8a of the press, the transport speed of the elastic band becomes constant. The surface velocity of the belt in contact with the web becomes the same as the surface velocity of the center roll in the 01 portion, where the belt is pressed against the baler. Set the surface velocity of the center roll of the press 8a to v, its radius to R, the distance from the core from the point of contact with the paper with the center line of the nip to t'2 and the velocity of the core regardless of the thickness of the paper will be: R + t'2 Core velocity = V x Meanwhile, in section 02 from the nip point E formed with the center roll 8a of the press and the press roll 50 to a point where the belt moves away from the pressure roll 50, the surface velocity of the side of the belt in contact with the web can be calculated as follows, with the pressure roll 50 radius set to r, the distance from the core 59 to the surface of the band to t2 and the distance from the core 59 to the back of the band to ti: r + tl + t2 Band speed = core speed xr + tl Generally due to R >> t'2 being the band speed in section 02 approximately: tz (1 + ----) V r + tl In the conventional cases, where the web is peeled off with an open 509 288 7 pull, the pull is normally 3-4% or lower, so that a sufficient features can be obtained for to remove the web from the center roller, if tz / (r + tl) is set to 1.0%, taking into account any slippage between the belt and the web. If the belt tension is to be guided, all that needs to be done is to adjust the web's sliding on the belt surface by influencing the pressure center roller's pressure force on the pressure rollers and changing the belt thickness (t'2).

Fig. 4 then describes the manner in which the web is transported from the belt 55 to the 4P blanket in the process following the above-mentioned removal unit. In Fig. 4, the 4P felt 12 is pressed against the belt by the vacuum roller 51. Said vacuum roller consists of a cell 60 with a plurality of openings 62, vacuum box 63, and sealing gasket 61 intended to prevent air leakage between the vacuum box and the cell. An illustrated vacuum pump is connected by a tube to the vacuum box 63. The belt 55 consists of two elements, one of which is the core 59 reinforced with reinforcing wire crosses which are less likely to extend when exposed to tension and the other elastic member 57, which is allowed to contract. or expand in an elastic manner. Fold 58 (Fig. 5) is created at the periphery of the surface of the elastic member 57. Fold 58 runs in several lines in the width direction. The elastic part 57 is designed so that it becomes harder and less elastic the closer one gets to the dividing plane with the core 59 without breaking off from the core. If a vacuum force acts on the vacuum roller 51, air G passes through several fold lines 58 and then through the web 2 and the 4P blanket 12 to flow into the vacuum box 63. This air flow passing through the web transfers the web deposited on the belt to the 4P felt 12 and to the next party, the fourth press. The example of the belt shown in Fig. 4 describes folds created along the periphery, but folds can be replaced with opening 64 extending through the belt, as shown in Fig. 6. Openings in the vacuum roll cell 60 can be created as disk opening 65 to obtain keep a larger contact area with the blanket, which makes it twice as safe for the web to be transferred to the blanket side. In the following, the second example is described which shows how the present invention was used. This second case differs from the first case in that the strip is pressed against the press center roller 8a by a press roller 50 to peel the web from the press center roller. In Fig. 7, a pressure roller 50 is pressed against the center roller 8a. A support roll 66 is placed opposite the pressure roll 50 with the felt 12 laid out in such a way that a winding angle around the press roll 50 arises. This results in the web shifted from the press center roller 8a by the belt 55 being squeezed between blankets and safely transferred to the subsequent process without falling off the belt. The vacuum roller 51 is arranged to touch the top roller 8b of the fourth press, which ensures that the web is transported to the top roller 8b while being held by a vacuum force.

As an explanation of the operations in removing the web in the above-mentioned second example based on Fig. 3, it can be mentioned that the elastic band touches the center roller 8a in the CD portion, as shown in Fig. 3. The tape measuring the web has a surface velocity equal to the web speed at point E, where the pressure is maximum. Set the distance from the core under the nip to the surface of the belt measuring the web to t'2, R + tf2 Tape core velocity = vx RI section 62 is the surface velocity of the belt measuring the web: r + t1 + t2 Tape core velocity xr + tl t'2 tz = V (1 +) (1 + ----)> VR r + tl The surface speed of the belt begins to decrease near C on the press center roller, where it comes into contact with the web and the speed becomes the same as for the web at point E, where the force pressing against it is maximum (the surface of the belt is at the distance t2 from the core). Then the surface of the belt moves faster and, after leaving point D, it travels in section 02 at the speed calculated below, achieving the necessary volume of draft to peel the web from the press center roller: 509 288 t'2 tz t2 v (1 + -) (1+) = v (1+ R r + t1 r + t1 In this case, the described operations are performed to transfer the web from the top roll 8b in the fourth press to the next process, the drying section. the arrangement of a pressure roller 70, belt drive roller 72, tension roller 73, guide roller 74, belt 75 and vacuum roller 71 inside the dryer coil.

The web which is pulled off from the top roller 8a by the action of the belt 75 applied by the pressure roller 70 is clamped between the canvas 78 and the belt 75 and transferred to the canvas by the vacuum pressure effect of the vacuum roller 71, before it is transported over to the drying section.

As described above in either of the first or second cases, the surface of the elastic band facing the web moves constantly while in contact with the web at the same speed as the web or faster and when moving at a higher speed at and after the point of maximum pressure, the surface of the belt can develop sufficient tensile stress to peel off the web from the press center roller even if the open tension is kept at zero. In either case, when the surface of the belt has folds or openings passing through the belt, as shown in Figures 4 and 5, air is sucked into the vacuum roller through the web, causing the web to be transferred to the next blanket or canvas. The web produced in the wire section is led after it has been pulled up by the suction receiving roller to the drying section together with the blanket or canvas without any need for any open drawing part, where only the web is transferred. This is the reason why no paper breaks occur. Without giving any details here, however, in both cases the pressure roller, the belt drive roller, the clamping roller, the guide roller and the others are all supported by a beam 79 which extends over the entire width with a cantilever ring, and has a suitable construction for belt changes.

A shower 80, cleaning roller 81 and scraper 83 can also be installed to clean the belt. In the case of the method of passing the paper through the drying section, the construction of which does not extend through the entire web width, it is permissible to use the conventional method of producing a tail in the wire section, passing said tail through the dryer and then expanding it to the full 509 288 10 tissue paper. However, the material in the part of the tail that has been cut with high-pressure water sometimes connects with each other due to pinches in the drying section. In such a case, one can also install a tail-creating high-pressure water jet 84 after the last press in the press section. Each example in which the invention is practically used shows that the elastic band is pressed against the hard roller by a rotating pressure roller, but there is no need to have the pressure roller rotating. In fact, the part that meets the band only needs to be wavy.

The application of a lubricating liquid between the belt and the arcuate surface of the press device can prevent friction and heating.

As explained in detail above, the invention has no open feature between the press sections or between the press and dryer sections, which has stood in the way of increasing the speed of papermaking, which consequently reduces paper breakage and takes a long step towards improving speed and efficiency. degree for the paper machine. The invention does not include the traditional operations of passing the paper through the machine, the work requiring considerable knowledge and taking a long time.

This means improved safety and shorter time for setting up the paper machine. In short, the invention greatly contributes to improving the efficiency of the machine.

Claims (6)

11 509 288 P.ans. No. 9202520-4 PATENT CLAIMS A web removal system in a press section of a paper machine, characterized by an endless belt (55) having a first surface which is elastic, which is structured and arranged to be in direct contact with a web in the press section, and a second surface which is not in contact with said web (2), the endless belt having an inner core (59) located between said first and second surfaces, said inner core being made of a material less elastic than said first surface; a hard roller (8a) for supporting the web; and two pressure rollers (50, 56) which press said endless belt (55) into direct contact with the web and against said hard roller around a sector of the hard roller, wherein when the endless belt is pressed against the hard roller it is deformed so that it directly removes the web from the hard roll and transports the web with the endless belt. _ Removal system according to claim 1, characterized in that it further comprises a belt drive roller (52) for driving the belt. Removal system according to claim 2, characterized in that it further comprises a tensioning roller (53) for providing tension in the belt. Removal system according to claim 3, characterized in that it further comprises a belt guide roller (54). Removal system according to claim 1, characterized in that it further comprises a suction roller (51) with a plurality of holes (62) on an outer surface thereof, and that the belt (55) has a plurality of grooves (58) which are formed in a web-bearing surface. on the belt and which together with said plurality of holes on the outer surface of the suction roll serve to guide the web to either of a blanket and a canvas after the web has been transferred from the hard roll to the belt. Removal system according to claim 1, characterized in that it further comprises a suction roller (51) having a plurality of holes (62) on an outer surface thereof, and that the belt (55) has a plurality of holes (64), which together with said plurality of holes on the outer surface of the suction roll serves to guide the web to either of a blanket or canvas after it has been transferred from the hard roll to the belt.