FI105838B - Process and device for positioning a calender roll - Google Patents

Abstract

The invention relates to a process and a device for positioning a calender roll. A paper web W to be calendered is fed into a calender 10 through calendering nips N1-N4 formed by an upper roll 13, a lower roll 14 and at least one intermediate roll 15, 16, 17 disposed between the upper and lower rolls 13, 14. The bearing housing 152, 162, 172 for the intermediate rolls 15, 16, 17 is mounted on base parts 151, 161, 171 which, by means of guides 30; 35, are movably disposed in a frame 11 of the calender. The position of the calender roll 15, 16, 17 is determined, at least when the roll assembly is open, according to the position of an opening and closing friction-locked connecting element 40. In order to support the base part 151, 161, 171 for the roll, the particular friction-locked connecting element 40 is fixed to the guide 30/35 by means of a remote-controlled function device. <IMAGE>

Description

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T0583P

Method and apparatus for positioning a calender roller Förfarande och anordning för placering av en kalandervals 4

The invention relates to a method for positioning a calender roll in a calender, wherein the paper web to be calendered is passed through calendering nips formed by at least one intermediate roll arranged between the upper roll, lower roll and upper and lower rolls, and wherein .

More particularly, the invention relates to a method in a calender, wherein the bearing housings of the intermediate roll (s) are pivotally mounted on the base members, and wherein the intermediate rollers are supported by power means arranged between the bearing housings and the lever members and bearing members supporting the bearing housings, e.g.

The invention also relates to a device for positioning a calender roll in a calender, wherein the paper web to be calendered is arranged to pass through calendering nipples formed by at least one intermediate roll arranged between the upper roll, lower roll and upper and lower rolls, and wherein the bearing housings fitted to the calender body.

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A conventional conventional supercalender roller set comprises a plurality of rollers, for example 25 to 14 rolls arranged in stacked roll rolls. During driving, the overlapping rolls are in nip contact with one another and the calendering paper web is arranged to pass through the nips between the rolls. The track is normally attached to the calender body by means of lifting spindles and guides. In one prior art solution, the bearing housings of the roller rollers are secured to the base members mounted on the vertical guides 30 in the calender body, which position the roller in the machine direction, i.e., keep the nip line straight. When the track is open, the vertical positioning of the heel sections is performed by means of the lifting spindles and the nuts on them. Each roller head portions lying in two -lObbäl so I'm on the spindle nut, which in the unloaded state of the set of rolls hanging by lifting spindles. Such prior art has been described e.g. DE 20 10 322, US 4 901 637 and EP 138 738. In addition, the calenders described in US 4 901 637 and EP 138 738 are provided with lightening devices for treating so-called. relieve pin loads when the calender is in running position. Leverage reduction refers to the partial or complete support of masses outside the width of the web to be calendered for each roll and peripheral devices attached to the roller bearing housings, such as scrapers, shield guards, or output roller masses. In the solution of US 4,901,637, the lightening devices are disposed between the spindle nuts 10 and the base members of the rolls, whereby the lightening forces are received by lifting spindles and spindle nuts. In the calender of EP 138,738, on the other hand, the lightening devices are arranged in connection with the vertical guides in the calender body. The lifting arms and spindle nuts are thus not involved in receiving the relief forces in this embodiment.

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Further, solutions are known in the art in which the bearing housings of the roller rollers are not mounted directly on the heel members, but rather the bearing housings are pivotally mounted on the heel members by means of articulated levers. Such calendars have been described e.g. 20 in FI 83 346 and FI 94 067.

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The drawback of calenders with auto-threaded spindles is, by its construction, the drawback that the spindle system comprises a large number of discrete moving parts such as spindle motors, spindle nuts, latches, etc. and a plurality of limit switches monitoring the operation of the previous 25. The hardware is thus quite complex and expensive. In addition, it has emerged that prior art threaded - · · automatic lifting spindles require quite a lot of maintenance, in fact, in some cases, this equipment is considered to be the most maintenance component of the supercalender. In large machines the dimensioning of the spindle causes a problem due to the large mass of the roller. The diameters of the spindles are of the order of 200 mm and nevertheless the spindles are within the limits of their endurance.

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The object of the present invention is to provide an improvement over prior art solutions. To accomplish this, the method β of the invention is essentially characterized in that the position of the roll, at least when the roller is open, is determined by the position of the frictional fitting to be opened and closed by the remote control actuator.

Specifically, the method comprises positioning the roller rollers and adjusting the nip quick release intervals by moving the roller lightening cylinders to their roller open position with the heels 10 in the highest position relative to the bearing housings, followed by lower rollers to lower the roller. the top nip quick release slot and the top intermediate roller base portions are secured to the guide, after which each intermediate roll is lowered from top to bottom by the quick opening gap and securing the base portion until all quick 15 opening gaps have been adjusted.

The device according to the invention, in turn, is essentially characterized in that the device comprises a friction-lockable fitting which can be opened and closed by means of a remote actuator adapted to attach to the guide by frictional force over the guide roll 20 supporting the entire roll weight.

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The invention provides several significant advantages over the prior art, of which the following may be noted. In the first embodiment of the invention, the conventional threaded spindle is replaced by a smooth guide, most preferably a circular smooth guide, which is of very simple construction and therefore inexpensive. Such a smooth conductor can be mounted directly on existing calendars in place of a helical mandrel, which makes the invention very advantageous in the modernization of calendars. The smoothly conductive guide has a significantly better strength than the threaded spindle.

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The smooth conductor can be utilized to reinforce the calender body such that the conductor can be secured at both ends to the calender body and biased, whereby the conductor is used as a draw bar to substantially reduce the loads on the actual body. Especially when modernizing a cast-iron old machine, this plays a significant role. However, when used as a draw bar, it does not affect the performance of the guide in supporting the track. The susceptibility to interference is lower than the current spindle because the structure of the invention does not hang as easily as a conventional spindle, the solution does not include latching mechanisms controlling the operation of the relief nuts and associated fouling malfunctions, nor does the device include a fragile spindle motor. During the modernization of the machine 10, the downtime is very short and the required body changes are minimal. Hardware is easy to automate. Due to its structure, the order of the tracks on the track can be varied almost arbitrarily. For roll replacement, it is possible to position the rolls easily with maximum working space around the roll being replaced. By using 15 tracks with articulated brackets as the track, it is possible to control the high-frequency oscillation of the track, called the Barrin-g, by driving the machine so that not all nipples are aligned.

The invention will now be described, by way of example, with reference to the accompanying drawings.

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Figure 1 is a full schematic side view of a calender employing the method of the invention.

Figure 2 is an enlarged detail of Figure 1.

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Figures 3A and 3B schematically illustrate a frictional joint used in a solution according to a first embodiment of the invention.

Figure 4 is a schematic side view corresponding to Figure 1 showing a calender according to another embodiment of the invention.

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Figure 5A is an enlarged detail of Figure 4 and Figure 5B shows a top view of the structure of Figure 5A.

Figure 5C is a further enlarged detail of point C of Figure 5B.

In Fig. 1, the calender is generally designated by reference numeral 10. The calender 10 comprises a calender body 11 with a roll stack 12 of multiple rolls mounted vertically. The roll stack comprises a top roll 13, a lower roll 14, and a plurality of intermediate rolls 15-17 arranged between the top roll and the lower roll 10. arranged in the driving position of the calender so that they are in nip contact with each other. The paper web W is guided to the top of the calender Nj and then through the other calipers N2 to N3 and finally out of the nip N4. Between the nipples N 1 to N 4, the paper web W is taken off the roll surfaces by means of the take-up rollers 155, 165, 175.

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Preferably, the calender top roll 13 is a deflection compensated roll and is provided in the embodiment of Figure 1 with a top cylinder 132 attached to a calender body 11 at each end of the roll whose piston acts on the top roll bearing housing 131. The axis of the deflection compensated top roll 13 is mounted on said bearing housing with internal loading devices for adjusting the deflection and loading of the roll casing as desired. The calender body 11 is provided with vertical guides 30 to which the bearing housings 131 are movably mounted and along which the bearing housings 131 can be displaced by the upper cylinders 132. The top roll 13 may be a hard surface roll or be provided with a soft coating, for example a flexible polymer coating.

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Similarly, the calender lower roll 14 is preferably a deflection compensated roll having a roll casing rotatably mounted on the roll axis and provided with internal loading means for adjusting the roll casing deflection and roll bearing force as desired. are vertically displaceable by lower cylinders 142. In this embodiment, the lower roller bearing housings 141 are also mounted on vertical guides 30 along which said bearing housings 141 can be displaced by the lower cylinders 142. Naturally, the lower roller could also be mounted on the calender frame The lower cylinders 142 thus allow the roll stack 12 to be opened and closed in a conventional manner. The lower roll 14, like the upper roll 13, may be a hard roll or a soft surface, preferably with flexible polymer coating.

As already described above, a plurality of nip rollers 15-17 adapted to nip contact are arranged between the upper calender roll 13 and the lower roll 14. Figure 1 shows a calender using three intermediate rolls, but it is clear that the number of intermediate rolls 10 may vary from, for example, one to fourteen. The intermediate rolls 15-17 may be either hard or soft-surface rolls, or the roll stack 12 may consist of a combination of hard and soft-surface rolls. When using soft-surface rolls, it is also advantageous to use rolls with a flexible polymer coating as intermediate rolls. Suspension of intermediate rollers, more clearly shown in Figure 2, is implemented such that the bearing housings 152, 162, 172 of intermediate rolls 15, 16, 17 15 are mounted by pivot arms 153, 163, 173 on pivot parts 151, 161, 171. 171 bearing housings 152, 162, 172 and pivot arms 153, 163, 173 thus form a pivot. The base members 151, 161, 171 are movably mounted on a vertical guide 30 mounted on the calender body 11.

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In the embodiment of Figures 1 and 2, the calender 10 is further provided with vertical smooth guides 35 to replace the threaded spindles for conventional calenders. In the example of Figure 1, these vertical guides are still attached at their upper end to the calender body 11, but the guides 35 may also be used to reinforce the calender 25 body 11 such that the guides 35 are also secured to the body 11 at the lower end and biased. The conductors 35 are preferably round in cross-section, but other forms of cross-section may also be used. Like conventional calipers with lifting spindles, the base 151, 161 of the rolls 15-17 are provided with stops or corresponding lugs 156 which are movably aligned with the conductors 35 in the longitudinal direction.

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Now, in the calender according to the first embodiment of the invention according to Figures 1 and 2, smooth, preferably circular guides 35, frictional joints such as those illustrated in Figures 3A and 3B are used. Although many different types of frictional joints are known in the past, in the case of the invention, the joint of Figures 3A and 3B for a smooth axial body may be considered as the most preferred solution. The connecting member according to Figures 3A and 3B is implemented in a so-called. 3A and 3B, said bellows 41 is disposed between the heel or, in fact, the heel member or the lug 10 and the guide 35. 3A such that the pressurized oil is directed to the larger surface area of the cone ring piston 42 whereby the cone ring piston extends the bellows 41 to cause high surface pressure on the abutment faces between the guide 35, the bellows 41, the cone ring piston 42 and the lug 156. The joint is self-holding, ie it holds 15 even when the oil pressure is released. Accordingly, the joint is disassembled by directing the pressurized oil to the smaller diameter end of the cone ring piston 42, whereby the piston 42 is pushed out of the cone, the bellows 41 is contracted and the original clearance between the surfaces is restored. In this embodiment, the bellows 41 locks each heel 151, 161 firmly into the guide 35.

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The positioning of the rolls of the roll stack 12 and the adjustment of the quick-opening intervals is first carried out by lowering the articulation rolls by means of the relief cylinders 164, i.e. by lowering the relief cylinders 164 completely, i.e. by allowing the bearing housings 162 to lower on the link arms 163. The roller 25 is then driven into position by the load cylinders, i.e., the top cylinders 132 and the bottom cylinders 142. For example, the lower cylinders 142 can also be used to drive the track, for example, when done, the lower cylinders 142 lower the track to the highest quick-opening gap, i.e. open the top nipple Nj. A suitable quick release slot for the top nip Nj is e.g. 8 mm. The frictional joint 40 is then locked, i.e. the base portions 151 30 of the upper intermediate roll 15 are secured to the guide 35 by the said frictional joint members 40, and then lowered to the guide 351 of the next roller 161 and thus continued until a suitable quick-opening gap is provided for each roll nip Nj-N4. In order to adjust the quick-opening gaps with sufficient precision, linear sensors are preferably provided in connection with the lower cylinders 142 for determining the movement of the lower cylinders 142. Once the roller rollers have been positioned 5 and the quick release intervals have been adjusted, the roller rollers can be moved to the running position, i.e. the roll nipples Nj to N4 can be closed by means of the lower cylinders 142 starting from the lowest nip. Once the nipples have closed, the spindle cylinders 164 can relieve the pin loads of the rolls as desired. Alternatively, the nipples can be closed in any desired order simply by means of relief cylinders.

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It is also to be considered as an equivalent solution to the invention that the spiral spindle is still used in the calender, i.e., the spiral spindle which is known for example from the present solutions can be "left in place". However, in this solution of the invention, the threaded spindle is fixedly fixed to the calender body, i.e., it is not rotated in the same way as when using prior art solutions. This eliminates the need for calender spindle motors, which can be removed from the machine. Therefore, in this respect, in its structure, this embodiment corresponds to that described in Figures 1 and 2 and described with reference to these Figures, with the exception that conventional threaded spindles are not replaced by smooth conductors, but the spindles are still provided with threads.

In the case of such helical spindles, instead of the frictional fittings shown in Figures 3A and 3B, respectively, form-fitting, openable and closing fittings are used which close around the threaded spindle and are provided with a shape suitable for the threaded spindle shape. Such a connecting member can be described, for example, as a "split" axially oriented or multi-piece spindle nut which closes around the spindle 25 and which can be opened from this closed form to an open position. Connecting member. . the parts may be, for example, hinged to one another or arranged to move radially outward and inward with respect to the threaded spindle. The pitch of the threaded spindle then determines which step the connecting member can be attached to the threaded spindle. It should be further emphasized that such a connecting member is not threaded over the threaded spindle, but is locked in a desired position defined by the pitch of the thread 30, from which position it can be opened immediately. The positioning of the calender rollers and the adjustment of the quick opening intervals such

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1, 2, 3A and 3B.

Fig. 4 shows a calender 20 using three spacer rolls, but the number of spacer rolls 5 may vary from, for example, one to fourteen. The intermediate rolls 25, 26, 27 may be either hard or soft-surface rolls, or the roll stack 22 may consist of a combination of hard and soft-surface rolls. When soft rollers are used, it is also advantageous in the embodiment of Figure 4 to use rolls with a flexible polymer coating as intermediate rolls. The suspension rollers, which are further illustrated in Fig. 5A, 10, showing the suspension of the upper intermediate roller, are formed such that the bearing housings 252, 262, 272 of the intermediate rollers 25, 26, 27 are pivotally pivoted on the heel members 251, 261, 271. Said heel members are movably mounted on vertical guides 30 attached to the calender body 21.

With reference to Figures 4, 5A and 5B, the following can be noted in more detail with respect to the suspension rollers 25, 26, 27. Reference will now be made in particular to Figures 5A and 5B, which show the hanging of the upper intermediate roll 25 as previously disclosed. The bearing housing 252 of the intermediate roll 25 is rigidly secured to the cradle 257 pivotally pivoted on the base 251 by the pivot 253. The pivot 257 further has a rigidly mounted pivoting arm 258, 20 extending opposite the pivot joint 253 to the roll bearing 252. Between each heel portion 251 and the pivot arm 258, a relief cylinder 254 is mounted, by means of which the pivot arm 258 is pivoted about the pivot joint 253, thereby changing the height position of the roll 25 relative to the heel portion 251. As previously mentioned, each base member 251 is movably mounted on a guide 30 in the calender body 21 25. The base member 251 is further mounted with a lower position stop 259,; : to limit the swinging movement of the swing arm 258 and the vertical movement of the roll 25 · "· - down.

The calender of FIG. 4 does not use at all the smooth, preferably circular, wire described in connection with the embodiment 30 of FIG. 1, replacing a conventional helical mandrel. In the present embodiment, the positioning of the rolls and the adjustment of the quick opening intervals are accomplished by locking the base portions of the rolls to a guide 30 on the calender body 21 along which the base portions slide. An attempt has been made to illustrate this solution in the representation of Figures 4, 5A, 5B and 5C. The principle of the solution according to this embodiment is that long movements, such as adjustments due to roller diameters 5, are made by load cylinders, i.e. lower cylinders 242, and then base members 251, 261, 271 are locked to guide rail 30 in frame 21 by special braking devices 50 such as Figs 5A, 5B, 5C. more closely present. The intermediate rollers 25-27 are thus attached to the calender body 21 only through the guide 30 in the body, so that installation of the rolls and the entire track system is quick. The braking devices 50, which in the figure representation have three pieces for each base member, are spring-operated, i.e. the braking devices 50 are locked to the guide 30 by a spring. The brakes are released with a hydraulic release cylinder. As shown in Figs. 5B and 5C, the guide 30 in this embodiment is specifically shaped to have laterally machined grooves 31 for the brake pads 51. The grooves, and in particular their shape, provide space for the brake shoes without widening the structure, which jamiken-15 has to be quite rigid, since the spring-loaded brake means 50 do not give them a steady load on the brake side. The wedge-shaped shape of the grooves, or friction surfaces, improves brake performance at 90 ° groove angle by about 40% compared to straight surfaces.

4, 5A, 5B, 5C, the principle is that the roller diameter adjustments and other long movements are made by the load cylinders 242 and the roller shafts 251, 261, 271 are locked to the housing 21 I · rail 30 by means of spring-loaded brakes 50. The base roll portions 251, 261, 271 are displaced mainly only when the roll diameters are changed. The relief and quick release are made by the respective relief cylinders 254, 264, 274 of each roll 25, 26, 274. 25 Suspension of the intermediate rolls 25, 26, 27 thus consists of the base members 251, 261, 271 and. . e.g., the bearing housings 252, 262, pivotally mounted as shown in Fig. 4. . 272. Owing to their articulation, the bearing housings are able to move relative to the heel parts for quick opening.

30 Linear bearings between the base members 251, 261, 271 and the guide rail 30 of the calender body 21 may be provided with life-lubricated bearing suspensions, whereby any lubricant may not be applied to the braking devices 50, which have a central function. The guides 30 may also be protected by, for example, bellows guards such that oil or impurities cannot enter the brake means 50 from the outside.

The invention has been described above by way of example with reference to the embodiments shown in the figures of the accompanying drawings. However, the invention is not limited to the examples shown in the figures, but different embodiments of the invention may vary within the scope of the inventive idea defined in the appended claims.

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Claims (17)

12 105838 A method for positioning a calender roll in a calender (10; 20), wherein the paper web to be calendered (W) is introduced between the upper roll (13; 23), the lower roll (14; 24) and the upper and lower rolls (13, 14; 5 23, 24). through the calendering nipples (N 1 - N 4) formed by at least one intermediate roll (15, 16, 17; 25, 26, 27), and wherein the bearing housings (152, 162, 17, 25, 26, 27) of the intermediate roll (s) (15, 16, 17; 172; 252, 262, 272) are mounted on base members (151, 161, 171; 251, 261, 271) which are movably fitted to the calender body (11; 21) by means of guides (30; 35), characterized in that the roll ( 15, 16, 17; 25, 25, 27) the position 10, at least when the rack is open, is determined by the position of the frictional fitting (40; 50) to be opened and closed, which frictional friction member (40; 50) , 261, 271) is fastened to the guide (30/35) by means of a remote actuator. A method in a calender (10; 20) according to claim 1, wherein the bearing housings (152, 162, 172; 252, 262, 272) of the intermediate roll (s) (15, 16, 17; 25, 26, 27) are mounted on the base members (151). , 161, 171; 251, 261, 271) pivotally, and wherein the intermediate rollers are supported by means of force arranged between the bearing housings and the base members or the levers and the base members supporting the bearing housings, such as hydraulic relief cylinders (154, 164, 174, 2754, 264, characterized in that the positioning of the roller rollers (13-17; 23-27) and the adjustment of the quick-opening intervals of the nipples (Nj-N4) are carried out by driving the roller lightening cylinders (154, 164, 174; 254, 264, 274) with the base members in the highest position relative to the bearing housings, after which the lower rollers (142; 242) of the track roller drive the track (12; 22), further lowering the track with the upper nip (Nj). ) for the quick-opening gap j a. the base portions (151; 251) of the uppermost intermediate roll (15; 25) are secured to the guide (30/35), after which each intermediate roll is lowered from top to bottom by the quick-opening gap and secured in position until all the quick-opening intervals have been adjusted. * 13 -1Ub838 Method according to Claim 1 or 2, characterized in that a smooth conductor (35) is used in the calender (10) to replace the conventional helical spindle, to which the frictional connecting member (40) is attached. « Method according to Claim 3, characterized in that, when positioning the roller and adjusting the quick-opening intervals, the intermediate portions (151, 161, 171) of the intermediate rollers are rigidly locked by said smooth guide (35). Method according to Claim 2 or 3, characterized in that, when positioning the roller assembly 10 and adjusting the quick-opening intervals, the frictional connecting members (40) are locked in a smooth guide (35) such that the base members (151, 161, 171) ) will rest on these frictionless fittings (40). Method according to one of Claims 3 to 5, characterized in that said smooth conductor (35) is used at both ends as a prestressed tension rod attached to the calender body (11). Method according to Claim 1 or 2, characterized in that the base portions (251, 261, 271) of the intermediate rollers (25, 26, 271) are fastened by means of a frictional closure member (50) to a vertical guide (30) attached to the calender body (21). otherwise the heels are slidably mounted. A method according to claim 7, characterized in that the attachment of the base members (251, 261, 271) to the guide (30) is effected by a spring-operated and hydraulically detachable brake device (50). A device for positioning a calender roll in a calender (10; 20), wherein the calendering paper web (W) is arranged to pass through the upper roll (13; 23), the lower roll (14; 24) and the upper and lower rolls (13, 14; 23, 24) through at least one intermediate roller (15, 16, 17; 25, 26, 30 27) formed by at least one intermediate roll (15, 16, 17; 25), and in which calender the intermediate roll (s) (15, 16, 17; 25, 26, 27) bearing housings (152, 162, 172; 252, 262, 272) are mounted on base members (151, 161, 171; 251, 261, 271) movably adapted by means of guides (30; 35) calender body (11; 21), characterized in that the device comprises a friction-lockable fitting (40, 50) which can be opened and closed by means of a remote actuator adapted to engage the guide (30/35) by a guide (30) / 35) with a directional frictional force for determining the position of the roll head (151, 161, 171; 251, 261, 271) or its position or for securing the brace (156) to the guide (30/35). Apparatus according to claim 9, characterized in that the frictional coupling member 10 is a spring-loaded brake device (50) which compresses the vertical conductor (30, 35). Device according to Claim 10, characterized in that the frictional connecting member (50) is hydraulically releasable. Device according to Claim 9, characterized in that the frictional connecting member is a device (40) providing a frictional force with the vertical conductor (30). Device according to Claim 12, characterized in that the wedge element of the frictional coupling member (40) is hydraulically movable. Device according to one of Claims 9 to 13, characterized in that the frictional connecting member (50) is adapted to cooperate with a guide (30) attached directly to the calender body (21), to which the base rollers (251, 261, 271) are slidably fitted. to which said connecting member is arranged to be fastened. Device according to one of Claims 9 to 13, characterized in that the frictional connecting member (40) is adapted to cooperate with a separate wheel or angular cross-section guide (35) to which said connecting member (40) is arranged to be fastened. 105838 15 Device according to Claim 15, characterized in that the frictional connecting member (40) is an annular member which generates frictional force around the conductor (35). Apparatus according to claim 16, characterized in that the frictional connecting member 5 (40) is provided with an annular key member (42) which is hydraulically actuated. • · »· • 9 9 *, 6 105P38