FI130174B - Quick-locking lifting arrangement and paper or board machine - Google Patents

Abstract

The invention relates to a quick-locking lifting arrangement (10) for carrying up and mounting a bearing housing (20) to the roller (12) of a fiber web machine (100), which roller (12) is a roller equipped with a belt jacket (16) and bearing housing (20) ( 12), for example a shovel roller (12), which lifting arrangement (10) comprises - a lifting point (18) on the bearing housing (20), - a lifting arm (24) to be operated with lifting devices (22) including a support point (28), - at least a support arm (30), - pin connection devices (40) on the bearing housing (20) lifting point (18) including at least one elongated directional hole (42) in said bearing housing (20) and an opening (44) in the support arm (30) and a directional pin (46) ), and said oblong directional hole (42) comprises a curved support surface (45), against which said directional pin (46) supports when the roller (12) is lifted, - deflection devices (38) for lateral movement of the lifting point (18) of the bearing housing (20) arranged to move said directional pin (46) in said elongated directional hole (42). The invention relates to a paper or cardboard machine.

Description

QUICK-LOCKING LIFTING SYSTEM AND PAPER OR CARDBOARD MACHINE

The object of the invention is a quick-locking lifting arrangement for supporting and installing the bearing housing of a roller of a non-woven machine at a selected angle, which roller is a roller equipped with a belt sheath and a bearing housing, for example a shoe roller, in which the lifting arrangement includes - a lifting point in the bearing housing, - a lifting arm to be used with the lifting device, including the support point formed by the alignment shaft, - at least one support arm adapted to bind the lifting arm support point and lifting point of the bearing housing to each other, - pin connection means at the lifting point of the bearing housing, comprising at least an alignment dowel in the bearing housing and an opening in the support arm and an alignment pin connecting the alignment dowel and the opening, and the alignment dowel includes a support surface against which the said alignment dowel rests when lifting the roller, and - deflection means for moving the bearing housing lifting point in the lateral direction, adapted to the connection of pin connection means which deviate feeding equipment are adapted to move the alignment pin in the alignment shaft.

The subject of the invention is also a paper or cardboard machine.

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S 25 Used in the manufacturing process of paper or cardboard

In the N press part, generally at least one e roller equipped with a belt sheath, for example a shoe roller. In connection with the maintenance of the shoe roller, z its belt sheath is removed from the ends of the shoe roller and threaded so lengthwise of the body of the shoe roller out of the end of the shoe roller. 3 30 During maintenance, the shoe roller is lifted off its counter roller, which

N together form a pinch pin when driving. Lift

N is done by means of a quick-locking lifting arrangement, lifting the shoe roller from the bearing housings.

When the shoe roller is lowered back onto the counter roller from its bearing housings, the contact surfaces of the shoe roller and the counter roller bearing housings must be aligned with each other. Often, in a press nip, the shoe roller and counter roller are in line with each other, so that the line is not directly vertical, but slanted in relation to the vertical. In this case, the contact surfaces of the bearing housings are also inclined relative to the horizontal plane. Furthermore, the locking devices between the shoe roller and counter roller bearing housings must also be aligned with respect to each other.

The level of technology is known from the applicant's own previous patent publication

FI 125072, which presents a quick-locking lifting arrangement, in which a support point that can be moved in the lateral direction is formed on the lifting arm of the lifting means by means of an alignment jig.

With lateral adjustment, the bearing housings can be aligned. On the other hand, the bearing housing includes the lifting point of the support arm between the lifting arm and the bearing housing, which can also be moved laterally.

The lifting point is formed by an alignment pin, which can be moved in the bearing housing's alignment shaft. With this adjustment, the lifting point of the roller suspension can be aligned to the desired point in relation to the center of gravity of the roller, so the roller can be turned around the lifting point to the desired angle to the lifting point and

N depending on the mutual location of the center of gravity.

Oh 25

N However, the problem with the lifting arrangement e according to the above-mentioned patent publication is that the adjustments of the angle of the bearing housing z are very limited, because the alignment gap cannot be increased indefinitely in the machine direction due to the large stresses acting on the bearing housing 3 30. Because of this

The N bearing housing must be designed separately for different applications

N depending on the installation angle used, for both operating and maintenance ends.

The costs of a single roller design project for bearing housings can be several thousand euros, and these costs are repeated again in subsequent projects.

In this way, in terms of rollers, you cannot benefit from the advantages of serial production, where multi-purpose rollers can be made based on one design with an optimized production process.

The purpose of the invention is to provide a quick-locking lifting arrangement that enables the use of the same roller in several different positions without changes to the structure of the roller. The characteristic features of this invention can be seen in the attached patent claim 1. The purpose of the invention is to create a paper or fiber web machine that is cheaper in terms of investment costs. The characteristic features of this invention are evident from the attached patent claim 11.

This purpose can be achieved with a quick-locking lifting arrangement for supporting and installing the bearing seat of the roller of the fiber web machine at the selected angle. The distinguishing feature of the lifting arrangement is that the alignment bracket includes a curved support surface against which the alignment pin rests when the roller is lifted.

In the lifting arrangement according to the invention, the tilt of the roller can be adjusted with the help of the curved surface of the alignment shaft

N increases significantly when adjusting the curved surface

O 25 at a distance that is longer than the corresponding straight support surface.

N On the other hand, the curved surface conforms to the direction of the outer circumference of the bearing housing e in the direction of which the loads on the bearing housing during the lift z of the roller are also parallel, thus reducing the stresses on the edges of the alignment shaft. The same 3 30 bearing housing can be used in several operating angles of the roller. This

N enables a pinch pin for the bearing housings of the rollers

N series production with the fewest variants, which can be used to significantly reduce manufacturing costs.

In the arrangement according to the invention, the pin connection means can be adjusted centrally or off-centered in relation to the roller's center of gravity, depending on the installation position. With an off-center placement, the fact that the bearing housing can be turned to the right angle with the help of the bearing housing's own weight is achieved by gravity, when the pin connecting means are deviated from the center of mass of the bearing housing in the lateral direction.

Advantageously, the origin of the radius of curvature of the curved support surface is located in the bearing housing on the line passing through the center of gravity of the guide plate and the roller. In this case, the curved support surface conforms to the shape of the outer circumference of the bearing housing with its curve.

Preferably, the origin is on the segment on the opposite side of the center point of the axis in relation to the direction field.

In this context, when talking about a fiber web machine, think of it as either a paper or cardboard machine, or alternatively a calender, where the lifting arrangement according to the invention can also be used.

The radius of curvature of the guide bar can be 5 - 10% larger than the radius of the roller. For example, I saw one with a diameter of 1300 mm

For N, the radius of curvature can be in the order of 700 mm.

Oh 25

N Advantageously, the alignment pin includes a counter support surface, which is curved and adapted to adapt to the support surface. In this case, z the counter-support surface has a considerably large surface area, which means that the surface pressure between the surfaces in contact is reduced and through this 3 30 the strength requirements and wear of the parts are reduced.

The counter support surface can form a secant in the cross section of the alignment pin, the width of which can be 10 to 20% of the entire cross section. In this case, however, the main cross-section of the alignment pin is round, which is an advantageous shape in terms of the strength of the alignment pin.

The width of the guide bar can be 130 — 250 mm. In this way, the width of the alignment beam 5 is such that a sufficient margin for adjusting the tilt of the roller is achieved, on the other hand, without widening the alignment beam too much, which could weaken the structure of the bearing housing.

Preferably, the lifting point is the same casting as the bearing housing, or a correspondingly shaped part fixed to it. In this way, the attachment of the bearing housing to the support arm can be arranged without separate spacers.

Advantageously, the lifting arrangement also includes upper pin connecting means at the support point, comprising an alignment beam in the lifting arm and an opposite longitudinal beam in the support arm, and an alignment pin connecting these alignment beam and longitudinal beam. With the upper pin connection means, the connection of the support arm to the lifting arm can also be made inexpensively and adjustable.

Preferably, the lower deflection means are integrated into the bearing housing. That way you don't need them at any point

N detaches from the bearing housing, which reduces the need for their adjustment.

Oh 25

N The shape of the bearing housing can be adapted to essentially follow the surface shape of the cross section of the e shoe roller at least = a third, preferably at least in the upper half of the circumference of the shoe roller's belt sheath. In this case, the parts of the bearing housing, 3 30, which are possibly in contact with the belt sheath, it

N in connection with the change, are following the shape of the shoe roller surface,

N and do not damage the material of the belt sheath.

According to one application form, the length of the support arm is at least three times as long as the diameter of the alignment pin. In this case, when lowering the roller back into place, the roller can be avoided with the lifting arm from breaking if the roller is accidentally pressed against the lower roller with the lifting arm. In this case, the alignment pin can move in the longitudinal direction of the longitudinal frame, so that the load of the lifting arm is not applied to the roller.

Advantageously, the support arm is connected directly to the bearing housing. This achieves a simple structure that is easy to manufacture and adjust.

According to one application form, the upper deflection means includes at least one actuator for moving the alignment pin in the alignment shaft, and the alignment pin can be placed inside a separate slide, which is moved using the actuator. With the aid of the slide, the dowel connecting means can be moved precisely in the alignment shaft to find a suitable adjustment for aligning the bearing housings.

According to one application form, the lower deflection means includes at least one control element for moving the alignment pin

N in the alignment bracket and the alignment pin can be placed separately

O 25 to the inside of the second sled, which the second sled is moved

N with the help of an adjustment element. With the help of the second slide, the pin connecting means e can be precisely moved in the alignment jig to find a suitable adjustment z for aligning the bearing housings. a 00 3 30 Advantageously, the bearing housing includes lugs at the end

N apart, between the lugs of which the Support Arm is fitted

N to be connected using pin connection means. The lugs enable the support arm to be attached directly to the bearing housing. There can also be only one fixed bearing housing lugs.

The lifting arrangement according to the invention can be manufactured from common iron alloys without special strong structures, because the lifting arrangement is formed directly into the casting of the bearing housing or otherwise as a fixed part of the bearing housing.

Preferably, the width of the alignment rod is 2 to 3 times as wide as the diameter of the alignment pin. In this case, a sufficient margin of adjustment is achieved in terms of orientation.

The lifting arrangement according to the invention is suitable for implementation with all body diameters and different installation angles.

A characteristic feature of the paper or cardboard machine according to the invention is that the paper or cardboard machine uses a lifting arrangement according to one of the aforementioned applications of the invention, and the pressing part of the machine has a total of two or more pinch nipples. In this case, it is particularly advantageous to use the lifting arrangement according to the invention, because in the case of several press nips, several different installation angles are used for identical rollers or at least identical

N for bearing housings. Lifting arrangement according to the invention

When using O 25, the same bearing housing can be used

N for all shoe rolls of the non-woven machine in all e press nips without structural changes only = by changing the adjustments. a 00 3 30 Preferably there are 2 to 4 press nibs.

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The tilts of the clamp nibs can be between 0 and 15°.

All of these installation angles can be reached using the lifting arrangement according to the invention. Preferably, a narrower tilting area is used, which results in a more precise adjustment.

It is most advantageous to use only a 5° difference in the inclination of the nips.

Advantageously, in each press nip, the bearing housing in each roller is identical. In this way, serial production can be used in the manufacture of rollers.

The lifting arrangement according to the invention enables serial production of bearing housings in the manufacture of rollers, because the same bearing housing can be used in different operating positions without changes thanks to the greater adjustment margin made possible by the lifting arrangement according to the invention.

The invention is described in detail in the following by referring to the accompanying drawings depicting some applications of the invention, in which

Figure 1 shows the connection between the shoe roller and its counter roller, viewed from the side,

Figure 2 shows an enlarged view of the support arm of the lifting arrangement according to the invention and the related parts in the direction of the shoe roller,

N Figure 3 shows the invention as a sectional view enlarged

The support arm of the lifting arrangement according to O 25 and to it

N connected parts shown transversely e of the shoe roller, z Figure 4a shows an enlarged principle view of the alignment bracket and the alignment pin so with the alignment pin 3 30 in the middle of the alignment bracket,

N Figure 4b shows the alignment bracket and the alignment pin

As a principle image of N magnification, with the alignment pin on the side of the alignment rod,

Figures 5a and 5b show the principle view from the side of the location of the lifting point in the bearing housing in different applications,

Figure 6 shows the pressing part of a paper or cardboard machine from the side as a principle view.

Figure 1 shows a general view of the connection between the shoe roller 12 and the counter roller 14 when the locking means 110 are locked. In the locked position, the bearing housing 20 of the shoe roller 12 and the bearing housing 20' of the counter roller 14 are aligned on their contact surfaces 100, so that the lugs 104 of the bearing housings 20 and 20' belonging to the locking means 110 are also aligned with the connecting arms 102 coming between the lugs 104.

In order to remove the belt sheath of the shoe roller 12 from around the shoe roller 12 when changing the belt sheath, the locking means 110 must be opened and the shoe roller 12 lifted into the air. The belt sheath 16 is shown in figure 2. At least the lowering of the shoe roller 12 back onto the counter roller 14 must be done with the lifting arrangement 10 according to the invention, because aligning the contact surfaces 100 with a standard crane is practically impossible or at least very difficult and time-consuming. Preferably, the lifting is also carried out with a lifting arrangement according to the invention.

N Figure 2 shows the lifting arrangement 10 according to the invention.

O 25 Only one end of the shoe roller 12 is depicted, but it will

N understands that naturally the shoe roller 12 has two ends. e The lifting arrangement is mainly intended for lowering the shoe roller z onto the counter roller in a controlled manner, but the so lifting arrangement is also used to lift the shoe roller off the counter roller 3 30 .

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According to Figures 1 and 2, the shoe roller 12 is supported on its axis 62 in the bearing housing 20. The lifting arrangement 10 includes a lifting point 18 in the bearing housing 20 and a lifting arm used with the lifting device 22

24 and the support point 28 formed by the alignment shaft 26 in the lifting arm 24. The lifting arm 24 can be articulated as shown in the figure with the joint 72 and the lifting means 22 to the frame of the fiber web machine 200. Between the lifting arm 24 and the lifting point 18 of the bearing housing 20 there is at least one Support arm 30, with which the supporting point 28 of the lifting arm 24 and the lifting point 18 of the bearing housing 20 are tied to each other.

The support arm 30 is better shown in figure 2. In other words, the shoe roller 12 is suspended from the lifting point 18 of the bearing housing 20 by means of the support arm 30 to the lifting arm 24. In order for the bearing end 20 to be oriented in relation to the bearing housing 20 of the counter roller 14, the lifting arrangement 10 includes deflection means 38 for moving the lifting point 18 of the bearing housing 20 laterally and pin connection means 4 0 bearing housing 20 at the lifting point 18, comprising at least the alignment bracket 42 in the bearing housing 20 and the opening 44 in the support arm 30 shown in Figure 3, and the alignment pin 46 connecting the alignment bracket 42 and the opening 44. The lateral direction or the lateral direction of the cross-sectional plane is meant in this context in the direction of the double-headed arrows shown in Figures 1 and 2, in connection with the tilting and alignment pins, i.e. the other way around in other words, the longitudinal direction of the lifting arm.

The opening 44 is shown in Figures 2 and 3. The deflection means 38 are adapted to the connection of the pin connection means 40 at the lifting point 18

To move N aside. Preferably according to the invention

The O 25 lifting arrangement uses one support arm, but

If necessary, several support arms articulated between the same centrally e lifting arm and the bearing housing can also be used. x a

LO According to Figure 3, the lifting arm 24 can be formed from two 330 parallel metal plates 92

N compound arm articulated as shown in Figure 1 from one

N end 70 is connected to the body 200 of the fiber web machine with the help of joint 72, and the other end 74 is connected to the lifting device 22 with the help of joint 76. Preferably, the support arm 30 is articulated between the metal plates 92 of the lifting arm 24 from the support point 28 as shown in figure 3. The lifting means 22 can be, for example, a hydraulic cylinder or a similar structure, which in turn is articulated at one end to the body of the fiber web machine 200. By changing the length of the lifting means 22, the lifting arm 24 can be raised or lowered, i.e. the support point 28 can be moved further or closer in relation to the counter roller. The structure of the lifting arm lifting equipment shown in the pictures is only one exemplary application form and it should be understood that the lifting arm can also be used with different structural solutions, for example with the help of two hydraulic cylinders. The structure of the lifting arm can also differ from the one shown in the pictures, as long as the structure is suitable for lifting the shoe roller.

Advantageously, the lifting arm 24 also includes the upper deflection means 48 of Figure 2, with which the support point 28 between the support arm 30 and the lifting arm 24 can be moved laterally. In other words, this means that the support point 28 can be moved back and forth substantially in the longitudinal direction of the lifting arm 24. With the help of the upper deflection means 48, the bearing housing 20 of the shoe roller 12 can be moved laterally in relation to the bearing housing of the counter roller, i.e. the shoe roller 12 can be aligned with the counter roller 14. Advantageously, the deflection means can be

N basically or completely similar in structure and

O 25 of the upper deflection means 48 and the lower ones

N for deflection devices 38. Advantageously, upper = pin connecting means 32 are also used between the support arm 30 e and the lifting arm 24. The upper pin connecting means 32 can therefore include at least an alignment groove 26 in the lifting arm 24 and 3 30 longitudinal grooves 34 in the support arm 30 and an alignment pin 36

N connecting the alignment groove 26 and the longitudinal groove 34.

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The lifting arrangement according to the invention is generally used in such a way that the lifting arrangement 10 is permanently attached to the bearing seat 20 of the shoe roller 12. In this way, the lifting arrangement can be used to lift the shoe roller remarkably quickly when the locking means between the bearing seats have been opened. The lifting arrangement is always used when removing/lifting the shoe roller, even when changing the belt sheath, the first lifting arrangement for the end of the treatment side is moved to the support of the changing device after lifting (usually with the help of a ceiling crane). However, the lifting arrangement is not used to load the roller during driving. In this case, the lower pin connection of the support arm is removed and the Support Arm is lifted out of the way in connection with the lifting arm. When removing the shoe roller, the lifting arrangements of both ends are removed after lifting and the roller is transported away from the machine with other lifting devices. The lifting phase is not so critical in terms of direction, as the shoe roller is free to position itself. When the shoe roller is lowered back into the bearing housings of the counter roller, a lifting arrangement according to the invention is needed.

With the help of the lifting arrangement, the lowering can be carried out in a very precisely controlled manner and much more precisely than with a roof crane. In relation to the counter, it is essential that the bearing housing of the shoe roller can be aligned and oriented with respect to the bearing housing of the counter roller with the help of deflection means.

For orientation, the lateral alignment of the bearing housing and the alignment of the contact surfaces of the bearing housings can be adjusted in the desired order.

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S 25 According to Figure 2, using the lifting arrangement 10, the bearing housing 20

N can be increased by at least 10%, preferably more than 15% of the diameter of the bearing housing e. The lifting clearance can be, for example, 100 to 300 mm. z In Figure 1, the possible position of the bearing housing 20 is shown with a broken line when it is raised. Advantageously, the lateral displacement of the bearing housing 20 of the shoe roller 12 is adjusted with the upper deflection means 3 30 48

N in relation to the lengthwise direction of the lifting arm 24 and with deflection means

N 38, on the other hand, the inclination of the bearing housing 20 in relation to the pin connection means. The lifting arrangement 10 has a shoe roller 12 at both ends in connection with the body 200 of the fiber web machine. The lifting arrangement according to the invention is suitable for use in connection with rolls of different widths, and the length of the roll can vary between 4 and 12 m, where length means the width of the web transverse to the direction of travel of the paper or cardboard.

The pin connection means 40 shown in Figure 2 are constructed in such a way that they include an alignment pin 46, which, as shown in the figure, is placed in the alignment bracket 42 formed in the bearing housing 20. The alignment pin 46 is movable in the longitudinal direction of the alignment bracket 42. According to the invention, the alignment bracket 42 includes a curved support surface 45, against which the alignment pin 46 rests when the roller 12 is lifted. According to Figure 3, the upper edge of the bearing housing 20 preferably includes two planar parallel lugs 94, i.e. plate surfaces at a distance from each other, between the lugs 94 of which the support arm 30 of the lifting arrangement is locked with the help of pin connection means 40. With the help of the lugs 94, a space for the support arm 30 has been arranged inside the circumference of the bearing housing 20, enabling the use of the pin connection means 40. Both lugs 94 include mutually identical slot holes, which together form an alignment slot 42 for the alignment pin 46. Preferably, the longitudinal dimension of the alignment pin 46 is such that the alignment pin 46

N extends between both holes of the directional bracket 42 at the same time

O 25 passing through the opening 44 in the support arm 30 as shown in figure 3.

N Preferably, the alignment pin is slightly wider than the opening. © z Figures 4a and 4b show in more detail the structure and operation of the direction sensor 42 so. The support surface 45 of the orientation bracket 42 is 3 30 formed curved, so that the tilt of the bearing housing

N adjustment allowance can be added without adding the directional bracket 42

N lengths in machine direction. This is important so that the size of the alignment shaft does not grow too large, in which case it could weaken the bearing housing, which would have to be compensated for, for example, by using larger material thicknesses or separate reinforcements.

The curved support surface 45 is longer in length than the straight support surface used in the prior art, and thus the transfer clearance increases when the alignment pin follows the curved support surface.

The shape of the curved support surface 45 conforms to the advantageous shape of the upper surface of the bearing housing, which is also curved. The loads acting on the bearing housing move parallel to the curved outer surface of the J bearing housing, so that the curved support surface in the alignment shaft also corresponds to this shape. In this case, the corners 47 of the alignment bracket 42 are also subjected to smaller stresses, which improves the durability of the bearing housing. According to Figure 2, the radius of curvature R of the curved support surface 45 is preferably 5 to 10% longer than the diameter of the roller 12 and the origin o of the radius of curvature R is located on the segment y piercing the center point of the axis 62 of the alignment shaft 42 and the roller 12. In other words, the curved surface 45 curves in the direction of the axis 62 of the roller 12.

The width of the guide bar can be 10 - 20%, preferably 13 - 18% of the roller diameter, in which case the parts surrounding the guide bar have enough distance to the edge of the bearing housing so that these parts, i.e. the isthmus, can withstand the stresses applied to them. The position of the guide bar in relation to the axis of the roller

N can be 60 to 80% of the roll radius, facing the roll axis

O 25 viewed.

N e Advantageously, the upper surface of the alignment pin 46 also includes a curved z counter-support surface 51, which conforms to the shape of the curved support surface 45 according to figures 4a and 4b. In other words, the radius of curvature of the curved counter-support surface 3 30 is essentially the same as

N curved support surface. Essentially with the same radius of curvature

N means that the difference between the radii of curvature is no more than 2% of the total dimension of the radius of curvature. In practice, converging curvature is advantageous. Preferably with a curved counter-support surface

51, the contact surface between the alignment pin 46 and the alignment shaft 42 multiplies, which reduces the pressure between the parts on the contact surfaces and thereby the stresses that are applied to the contact surfaces. This, in turn, reduces wear on the alignment pin and alignment shaft. On the other hand, the large contact surface increases the friction surface between the alignment pin and the alignment shaft and the force required for the transfer, so that the lower deflection devices are subjected to lower stresses to keep the pin connecting devices in place after alignment before the locking between the shoe roller and the counter roller using the connecting arms.

Both the curved support surface and the curved counter-support surface can be formed with a radius of curvature R that is 5 to 10% greater than the radius of the roller.

Advantageously, there are two separate implementation versions of the lifting arrangement according to the invention, where the only difference between them is the position of the alignment rod in the machine direction in relation to the center of mass of the roller. If we consider the center of mass to be located on an imaginary line that meets the outer circumference of the bearing housing at 0°, i.e. is vertical, the first application can be on a line with a twist on the circumference of 7.5"

N according to figure 5a and the second application in turn

At the O 25 point, each turn on the circumference is 345” clockwise in Figure 5b

In accordance with N With the first form of application, the installation possibility of roller e is achieved at an angle of 0 - 5 °, while with the second form of application z, the installation is at an angle of 5 - 10° in the press nip. a 00 3 30 Part of the pin connection means 40 preferably has an alignment pin 46

N can be pulled out, so that the Support Arm 30 can be removed

N from the bearing housing 20 of the shoe roller 12 for changing the belt sheath when the shoe roller 12 is supported on the belt changing means. For the orientation pin 46, the bearing housing 20 can include a support tray 82 (in fig

3), on which the alignment pin 46 can be partially supported. The trough 82 prevents the alignment pin 46 from falling when pulled out, because a steel pin with a diameter of 100 mm, for example, can cause great danger if it falls. According to Figure 3, locking means 73 can be attached to the alignment pin 46, which includes a locking arm 75, which can be turned to its locking position in the position-locking recesses 79 belonging to the support tray 82. The locking arm 75 is preferably bolted to the alignment pin 46 with the help of a bolt 81. With these, the alignment pin can be locked longitudinally in place in the locking and opening positions . At the same time, the lock arm functions as a piece from which the alignment pin 46 can be pulled into the support tray 82.

Advantageously, the alignment pin stays in the groove with the help of a securing chain fitted between the bearing housing and the alignment pin. Preferably, the support trough is connected to a frame plate formed around the alignment pin, which can be, for example, inside the bearing housing. The frame plate can move with the alignment pin laterally, so that the support tray also moves with the alignment pin and is always available to pull out the alignment pin in any operating position of the alignment pin on the other side.

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S 25 The support arm 30 can include manual actuators,

For example, the crank 80 in Figure 1, with which the Support Arm 30 can be turned e essentially parallel to the lifting arm 24, leaving more space for replacing the belt sheath z. a 00 3 30 The deflection means 38 can be, for example, an alignment pin 46

N hood screws on both sides or only the ones in picture 2

One adjustment element according to N, i.e. a setscrew 96, with which the alignment pin 46 can be moved. According to one application form, the alignment pin can be placed on the inside of a separate slide, in which case only the slide is pushed with the help of a grub screw while the alignment pin moves with the slide.

Preferably, the set screw 96 of the lower deflection means 38 is fixedly hinged or attached to the bearing housing 20 at one end and around the alignment pin 46 in connection with the alignment shaft 42 at the other end. The adjustment element of the upper deflection means 48, or preferably the grub screw 90, is in turn preferably hinged at one end to the lifting arm 24 and at the other end to the longitudinal frame 34 of the support arm 30 by means of an alignment pin 36. Both the upper pin connection means 32 and the lower pin connection means 40 can both be similar in structure.

Similarly, the upper deflection means 48 and the lower deflection means 38 can also be similar in structure.

According to Figure 2, the lifting point 18 and support point 28 of the support arm 30 can be moved in the lateral direction by about 30 mm in each direction relative to the center of the shaft with the help of deflection devices. The lower deflection means 38 can be used to move the lifting point 18 to the side from the vertical line of the center of mass of the bearing housing 20, whereby the bearing housing 20 turns according to how the center of mass is

N in terms of suspension in a vertical line. If the bearing housing 20

O 25 is to be hung in such a way that the contact surface 100 is completely

N horizontal, the lifting point 18 must be moved to the same vertical line as the center of mass of the bearing housing 20 e. If, on the other hand, the bearing housing 20 is to be tilted, the lifting point 18 is deviated from the vertical line 3 30 of the center of mass with the help of deviation selectors 38. The tilt of the bearing housing can be

N classes from 0 to 30%, preferably from 0 to 15%, by which is meant

N angles of the contact surface of the bearing housing relative to the horizontal plane. The angle can be counterclockwise or clockwise.

Figure 3 shows the cross-section of the support arm 30 in the longitudinal direction of the lifting arm. In this cross-section, the lifting arm 24 consists of two metal plates 92 spaced apart in relation to each other, both of which have slotted holes forming an alignment slot 26 (Figure 2) for the alignment pin 36 of the upper pin connecting means 32. According to Figure 2, the alignment pin 36 extends between the metal plates 92.

On the inside of the metal plates 92 of the lifting arm 24, the plates 91 of the cap screw acting as an upper deflection device are fixed around the alignment pin 36. With the help of the plates 91, the alignment pin 36 can be moved freely in the longitudinal direction of the alignment shaft of the lifting arm 24. Correspondingly, also the plates 93 of the lower cap screw 96 (figure 2) fitted between the lugs 94 of the bearing housing 20 around the alignment pin 46. With the help of the plates 93, the alignment pin 46 can be moved freely in the longitudinal direction of the alignment shaft 42 of the bearing housing 20. Figure 3 also shows how the longitudinal groove 34 is preferably considerably higher than the diameter of the alignment pin 36, enabling a small vertical movement of the support arm 30 without breaking parts of the lifting arrangement.

According to one application form, the deflection means can be a tilting or an alignment pin on both sides of the slide

The ones on the N side are longitudinal of the tilting or alignment shaft

O 25 screws that can be used to move the sled in that frame.

N According to another application form, the upper deflection means e can also be completely different from the pictures, for example rail z and sled, where the sled is articulated by the support point of the support arm and so the sled moves in the longitudinal direction of the lifting arm on rails. 2 30

N According to Figures 1 and 2, the bearing housing 20 is preferably shaped

N such that the outer circumference of the upper part of the bearing housing following the circumference of the belt sheath of the shoe roller 12 is at least one-third, preferably at least half of the way adapted to substantially adapt to the shape of the circumference of the shoe roller's belt sheath. Preferably, this section shaped like a circular or elliptical arc is precisely the upper side 99 of the bearing housing 20 in the operating position, so that, for example, when changing the belt sheath, the probability of damaging the belt sheath to the shape of the bearing housing is considerably reduced. The bearing housing of the lifting arrangement according to the invention can support the belt sheath during its installation. The curved surface of the bearing housing does not contain sharp surface shapes, protrusions or surface-machined corners that could damage the belt sheath when changing the belt sheath. In this way, in connection with the replacement of belt sheaths, the proportion of damaged belt sheaths against the bearing housing is eliminated compared to state-of-the-art bearing housing structures with sharp corners. In the lifting arrangement according to the invention, the upper surface of the bearing housing can be shaped to adapt to the shape of the cross section of the roller by using pin connection means.

Advantageously, the lifting arrangement according to the invention can be used on the press part of a paper or cardboard machine, but also a calender unit connected to the paper or cardboard machine or separate is an advantageous application in terms of the lifting arrangement according to the invention. In the cheapest

In the N embodiment, the lifting arrangement according to the invention 10

O 25 is used in a paper or cardboard machine according to the invention,

N which includes a press part 106 comprising two to four e press nibs 108, all of which use the lifting arrangement 10 according to the invention z according to figure 6. In this case, it is advantageous to use an arrangement for the press nips 108, where the first and second press nips are on the shoe roller 12

For N installation, 5° at an angle, and the last clamp nib 0°

N at an angle, i.e. completely vertical.

It is advantageous to use the lifting arrangement according to the invention with rollers with a diameter of 800 to 1500 mm, the length of which can vary between 4000 and 9000 mm.

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Claims (13)

PATENT CLAIMS 1. Quick-read lifting arrangement (10) for carrying up and mounting a bearing housing (20) to the roller (12) of a fiber web machine (100) on a shoulder at a desired angle, which roller (12) is one with belt jacket (16) and bearing housing ( 20) equipped roller (12), for example a shovel roller (12), which lifting arrangement (10) comprises - a lifting point (18) on the bearing housing (20), - a lifting arm (24) to be operated with lifting devices (22) including an elongated hole for alignment (26) which forms a support point (28), - at least one support arm (30) arranged to connect the support point (28) of the lifting arm (24) and the lifting point (18) of the bearing housing (20) to each other, - spigot connection devices (40) on the bearing housing (20) lifting point (18) including at least one elongated directional heel (42) in said bearing housing (20) and an opening (44) in the support arm (30) and a directional pin (46) which connects said elongated directional heel (42) with the opening (44 ), and said elongated directional heel (42) comprises a support surface (45), against which said directional pin (46) supports when the roller (12) is lifted, — deflection devices (38) for lateral movement of the lifting point (18) of the N bearing housing (20) arranged in connection with O 25 said pin connection devices (40), which said N deflection devices (38) are arranged to move said e directional pin (46) in said elongated directional heel (42), x characterized in that said support surface (45) is curved. 00 3 30 2. Arrangement according to patent claim 1, characterized in that the origin (o) of the radius of curvature (R) of the N bent support surface (45) is located N in the bearing housing (20) along a stretch (y) that goes via the elongated directional heel (42) and the roller (12) center of gravity (CG). 3. Arrangement according to patent claim 2, characterized in that the radius of curvature (R) is 5-10% greater than the radius of the roller (12). 4. Arrangement according to one of claims 1 - 3, characterized in that said directional pin (46) comprises a counter-support surface (51), which is bent and arranged to follow said support surface (45). 5. Arrangement according to any of claims 1 - 4, characterized in that the counter surface (51) forms a secant to the cross section of the directional pin (46), the width of which is 10 - 20% of the area of the entire cross section. 6. Arrangement according to claim 4 or 5, characterized in that the radius of curvature of said counter-support surface (51) is essentially the same as the radius of curvature (R) of the support surface (45). 7. Arrangement according to one of claims 1 - 6, characterized in that the width of the elongated directional heel (42) is 130 = 250 mm. 8. Arrangement according to one of the patent claims 1 - 7, characterized in that N reading devices (73) have been attached to the directional pin (46), which include a reading arm (75) and a support beam (82) protruding from the bearing housing (20), where said reading arm N (75) can be turned to its locking position in locking recesses e (79) which read the position and engage in the support slot (82). x a LO 9. Arrangement according to one of the patent claims 1 - 8, 3 30 characterized by the fact that the position N of the elongated directional heel (42) in the bearing housing (20) is at a distance (d) from the axis (62) which N in the roller (12) in the direction of the radius of the roller (12), which distance (d) is 60 - 80% of the radius of the roller (12). 10. Arrangement according to one of the patent claims 1 - 9, characterized in that the width of said elongate directional lug (42) is 2-3 times as wide as the diameter of the directional pin (46). 11. Paper or cardboard machine, which includes a press part (106) consisting of at least two press nips (108), both press nips (108) include - a roller (12) including belt jacket (16) and bearing housing (20) - a quick-read lifting arrangement for carrying up and mounting a bearing housing (20) to a roller (12) on a shoulder at a desired angle, characterized in that said lifting arrangement (10) is a lifting arrangement (10) according to any of the patent claims 1 - 10 and said press nip (108 ) is a total of two or more. 12. Paper or cardboard machine according to patent claim 11, characterized in that the inclinations of the press nip (108) in relation to the vertical are in the range 0 - 15°, preferably 0 - 10°. 13. Paper or cardboard machine according to claim 11 or 12, characterized in that in each roller (12) the bearing housing (20) is identical. N N O N N 0 I a a Te 00 O O N N O N