FI116482B - A method for adjusting the deflection of intermediate rolls in a multi-roll system of a papermaking machine and a method used in the method - Google Patents

Description

116482

Method for Adjusting the Deflection of Intermediate Rollers in a Multi-Roll Telaset of a Paper Machine and Method Used in the Method

The invention relates, for example, to a method 5 for adjusting the deflection of intermediate rolls in a multi-roll track of a paper machine according to the preamble of claim 1. The invention also relates, for example, to a multi-roll paper machine roll system according to the preamble of claim 5 having a system for adjusting the deflection of the intermediate rolls.

The multi-roll calender generally has 6-17 rolls on top of each other, and the rolls are substantially horizontal, with the stacked rolls forming a substantially vertical straight roll. Calendering nips remain between successive rolls forming the track. As the fiber path begins to be calendered, the calender calendering nipples are closed in a nip contact by raising the top roll or / and the bottom roll. In a multi-roll calender, the calendering fiber path generally traverses from top to bottom in the calendering nipples (hereinafter referred to as "nipples"), while calendering its surface.

15 There are several types of multi roll calendars. Nk. in the supercalenders, the top and bottom rolls are die-cast rolls, and the so-called intermediate rolls between the lowest and highest rolls are alternately soft-coated rolls and alternately die-cast, heated thermo-rolls. swivel nipple with two soft-faced rollers facing each other. The intermediate rollers are bearing from the bearing housings at the ends of the cylindrical body of the 20 rolls, and additionally the wide rollers. . steam boxes and other accessories are often connected to the cupboards. Supercalender '; ': Each roll is thus substantially horizontal in the roll, with the rolls forming one vertical calender in which the rolls overlap. The intermediate rollers are slidably mounted in vertical guides on the calender body. The intermediate roll ends also have roll pins rotating with the roll body, which are: slidably secured to the calender frame to ensure the roll rolls remain in position.

The nip pressures of an ordinary supercalender increase as the calender moves from the top; · 'Down. The supercalender aims to run with straight nipples, whereby the difference in deflection of the intermediate rolls is large. In contrast, in Optiload ™, the rolls are dimensioned to have • the same specific deflection, so that the specific deflection due to the weight of the intermediate rolls is the same. Deviations occur in the linear nip load of a given nip, due to the bearing housings at the ends of the intermediate rollers and accessories such as steam boxes, output rollers, shield covers and scrapers. These deviations 2,116,482 accumulate as they move from top to bottom in the track nipples, so that the nip load, or nip pressure, may vary considerably in the lower nipples, in which, in particular, the end portions of the nipples are considerably more loaded than other nipples. These so-called. the pin loads are removed by counter-forces to the bearing housings.

U.S. Patent No. 5,438,920 discloses a solution to the above problem of nip pressures as follows: The top and bottom rolls of a multi-roll calender are rolls in which a cylindrical roll shell rotates about a stationary roll axis with a roll shell mounted on its end housings mounted on a roll. The intermediate rolls between the top and bottom rollers of the calender have substantially the same 10 deflections. The ends of the cylindrical bodies of the intermediate rollers are rotatably attached to the bearing housings. Intra-roll loading means are provided on the roll shafts of the top and bottom rolls, inside the roll casing. It is also possible to load the track with external force on the top and / or bottom rollers of the track. In practice, external force is arranged to load the bearing housings. The load caused by the bearing housings and accessories at the ends of the intermediate roll-15s is described. in the solution, lightened by means of nipple load relief devices attached to the bearing housings of the intermediate rollers. The lightening means comprise a shaft attached to the calender body with a hydraulic cylinder lifting the end upwards. The solution of U.S. Patent No. 5,438,920 aims at 100% reduction of the track and associated equal deflection of the intermediate rolls, which prevents otherwise occurring line load profile errors.

The solution according to the above-mentioned US patent can effectively compensate for changes in the nip and line load profile due to the wear of the polymer surface of the intermediate rolls and the bearing housings and accessories at the end of the intermediate rolls: 25, allowing the calender to be driven . .: natural deflection of its intermediate roll. However, there is a disadvantage in the solution used. *, the fact that the intermediate rolls must have substantially the same natural deflection, which requires high precision in the grinding and manufacturing of the rolls. In addition, rolls with the same deflection easily become large and expensive in diameter. If the same deflection was not required for teloil-30, a 100% lighter track could be constructed from existing rolls in the supercalender.

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It is an object of the invention to eliminate the drawbacks of the prior art. Thus, the main object of the invention is to provide a multi-roll calender; · 'Whose nip and line pressure profile deviations due to the wear of the polymeric surface of the intermediate rolls and the additional loads and bearing housings at the ends of the intermediate rolls can be effectively controlled without the natural deflection of the intermediate rolls being required.

The invention relates, for example, to a method according to claim 1 for adjusting the deflection of an intermediate roll in a multi-roll roll of a papermaking machine.

The invention also relates, for example, to a multi-roll paper machine roll machine according to claim 5, which has a rigid system for adjusting the deflection of the intermediate rolls.

In the method, the deflection of the intermediate rolls is controlled by calendering the fiber web (W), whereby the nip load and line pressure profile of the roller is controlled by controlling the total load imposed by the roller upper roller and / or lower roller onto the roller. The deflection of the intermediate rollers is controlled by the torque adjusting means operatively connected to the roller pins of the intermediate rollers.

The multi-roll system used in the method has internal and external loading means connected to the top roll and the lower roll of the roll and there are two or more spacer rolls between the top and bottom roll which are provided with 15 pin nipple relief means. The system used in the track for adjusting the deflection of the intermediate rolls comprises bearing housings in the roll pins of the intermediate rolls, to which the torque adjusting means are operatively connected.

By the method of the invention and the multi-roll track used therein, it is possible to compensate for the deflection of the individual rolls in the multi-roll calender, which controls the total nip load of the track and reduces the nip of the intermediate rolls. '*; load so that the intermediate rolls no longer have to have the same tendency.

* t;,; In the method according to the invention, the deflection of the intermediate rolls is more precisely controlled by rotating the ends of the intermediate rolls around the supports connected to the bearing housings of the intermediate roller or the pins of the intermediate roller.

* t. ': 25 By means of torque controls connected to the pulleys of the intermediate rollers at the end of a single roller

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thereby providing a deflection opposite to the deflection of the roll, which can effectively compensate for inaccuracies in the manufacture of the roll and .11 deflection rolls due to the grinding of the roll.

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. ·. By the method of the invention and the multi-roll calendar used therein. Of the additional advantages achieved, it can be noted that the evenly loaded roller can be driven up to * substantially straight nipples. The method according to the invention also achieves the '* significant advantage that it is possible to use smaller diameter and thus cheaper rolls in the multi-roll system because the specific tendency of the individual rolls can be reduced.

The invention will now be described in more detail with reference to the accompanying drawings.

Figure 1 is a simplified schematic view of one end of a multi-roll calendar according to the invention when viewed from the side.

Fig. 2 is a diagram illustrating the principle of a method for adjusting deflection of an intermediate roll when a single intermediate roll is viewed from the side.

The multi-roll calender 1 of FIG. 1 consists of a plurality of rolls attached to a calender body (not shown) substantially horizontally and 10 substantially parallel to one another. The rolls form a substantially vertical track 11. The roll top 3 and bottom roll 4 are chuck rolls. 5 of the intermediate rolls between the highest and lowest rolls are polymer-coated rolls 51, 53, 54 and 56 and some of the heated chill rolls or thermo-rolls 52, 55 and 57. When driving the fiber path, the rolls are rolled into nipple-15 strokes in nipples 2; 21 ... 27. Fig. 1 shows only one side of the track as the other side is identical to it. The upper roller 3, the lower roller 4, and the upper intermediate roller 51 of the track roller are examined in more detail. The structures and means used for adjusting the nip load and torque of the intermediate rollers 52 ... 57 are similar to the pre-·. :.

'·' · * 20 The principle of adjusting the deflection of the intermediate roll 5 according to the invention has been clarified in Fig. 2 by considering the single spacer shown in more detail in Fig. 1; : forces applied to 51. The self-weight of the intermediate roll 51 exerts a downward pressure on the intermediate roll '*: a force causing the roll body to bend convexly downwards. The downward bending force of the intermediate roll is indicated in the figure as a force output F1 at the center of the pi-25 axis of the central tendon of the roll.

'···' The upper roller 3 of the track consists of a roller body 31 rotating about a static roller axis 32 as well as external loading means 33 (hydraulic cylinders). The non-tex load means are coupled to the la *: · · attached to the roll shaft 32. in addition, there are internal loading means (not shown in Fig. 30) within the roll which allow the weight distribution of the roll to be varied. The lower roller 4 of the roller is of the same type as the roller, consisting of a roller body 41 rotating about a static roller axis 42 and external loading means 43 (hydraulic cylinder blades). The external loading means are coupled to the bearing housings 44 mounted on the roll shaft. In addition, the internal loading means are provided within the roll to change the weight distribution of the rolls. It is possible to load the upper and lower rollers of the track with an external load, i.e. with hydraulic cylinders 33a and 43a connected to the bearing housings 34a and 44a. The load exterior of the rollers 31 and 41 adjusts the total nip load of the roller when closing the roller rollers to nip contact. The inner loading means of the rollers 31 and 41 5, in turn, compensate for the deviations in question. rollers bending.

In addition to the top and bottom roll nipple lightening means, each spacer has nip and line load lightening means to reduce the weight of the rolls as well as accessories on the rolls, such as steam boxes, take-out rollers, when moving down to the linear load at the track nipples. Next, the bearing housing 6 will be examined in more detail; 61a in the roll 51. The bearing housings 6 at the ends of the other intermediate rolls have a structure similar to the one shown in FIG. roller bearing housings. The ends of the cylindrical body 15 of the intermediate roll 51 are pivotally mounted on the bearing housings 61 at the ends. The bearing housing 61a includes a bearing housing body 611a and a nipple load relief member 612a attached to this body. The lightening member 612a, in turn, comprises a hydraulic cylinder 612a 'and a bearing housing mounting means 612a' which secures the bearing housing body 611a to the calender body (not shown).

. . 20, the bearing housing 7 attached to the end / roller pin 91a of the cylindrical body of the intermediate roll 51 will now be further examined; 71a structure. In other intermediate rollers, the bearing housings 7 have a similar structure. The end of the roll pin is pivotally mounted: ... · in the bearing housing, which in turn is secured to the calender body. Connected to the bearing housing '71a are torque adjusting means 8, 81 comprising a hydraulic cylinder 81; : ': 25,811a for loading bearing housing 71a and support 81; 812a located below the intermediate pin roller pin 91a.

When the intermediate roll 51 engages with a rotary roll pin 9; 2, a force F is applied to the bearing housing l * 71a at 91a, for example, by means of a hydraulic cylinder 811a, consisting of two force components perpendicular to the roll: ': 30 acting on the mid-span M and a mid-span I' ·. of that component Fb. As the intermediate roll 51 is now supported from the support point 812a, the downward force component Fa will now twist the force F downwardly around the support point 821a, thereby reducing the natural weight of the roll due to its own weight ... ... marked to affect the median longitudinal axis M 35 dalle by the resultant force F1 in the amount of component Fa. The above description of the force F deflection depiction has been somewhat simplified to understand phenomenon 6116482, because in reality the roll bending force F1 is approximately uniformly distributed on the force vectors along the roll length, whereby the counter force F actually reduces the deflection force F1 force vectors over the entire roll length.

Only one embodiment of the intermediate roll deflection control method 5 according to the invention has been described above, and it will be apparent to one skilled in the art that the method of the invention and the track system used therein can be implemented in many other ways within the claimed method and apparatus. Thus, other prior art lightening means, such as those disclosed in the aforementioned U.S. Patent No. 10, may be used as means for relieving the nip load of an intermediate roll.

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Claims (6)

116482 A method for adjusting the deflection of intermediate rollers (5) in a papermaking multi-roller roller (11) when calendering a fiber web (W), adjusting the nip and line load profile of the roller by controlling total loading of the roller upper roller (3) and / or lower roller (4) by reducing the load on the intermediate rollers (5), characterized in that the deflection of the intermediate rollers (5) is controlled by the torque adjusting means (8) operatively connected to the intermediate roller pins (2). Method according to Claim 1, characterized in that the total nip load of the track is controlled by means of inner loading means of the upper roller and / or external loading means (32) or internal loading means of the lowest roller and / or external loading means (42) and the load on the nipples of the accessories attached thereto is reduced by nip load relief means attached to the bearing housings (6) of the intermediate rollers. Method according to claim 1 or 2, characterized in that the deflection of each intermediate roller is controlled by torque adjusting means (8) consisting of supports (82) connected to the intermediate roller bearing housings (6) or intermediate roller pins (9) and to the bearing housings at the ends of the intermediate roll pins. from the coupled torque regulators (81) such that the ends of the intermediate rollers are pivoted around the supports by the torque regulators. A method according to claim 3, characterized in that at least part of the force (F) exerted by the torque adjuster (81) on the end of the intermediate roll is directed to • I · ,,; downward from the plane defined by the center span (M) of the intermediate roll (5). A paper machine multi-roll roller (11) having a system of intermediate rolls (5) or; ': For adjusting the deflector, wherein the upper roller roller (3) and the lower roller roller (4) have' ': connected internal and external loading means of the rollers and two or more intermediate rollers (5) provided with nip load relief means between the upper and lower rollers , characterized in that the system comprises intermediate rolls for the roll pins I! 1 (9) functionally coupled torque relief means (8). . ·. Track (11) according to Claim 5, characterized in that each of the spacers. the roll torque adjusting means (8) comprises hydraulic torque reducers (81) connected to the roller pin bearings (7) and two supports (82) supported by the v: roller bolts (2) or the bearing housings (6) at the ends of the roller. 116482