FI74525B - STOEDARRANGEMANG MELLAN GLIDSKORNA OCH BELASTNINGSKOLVARNA AV EN ZONREGLERBAR VALS. - Google Patents

Description

74525 1 Central support system for sliding shoes and load pistons on a zone-adjustable roll Stödarrangeraang Melian glidskorna och belastningskolvarna av en zonreglerbar Vale 5

The invention relates to a central articulated support arrangement for sliding shoes and load pistons of a zone-controlled roll, the roll comprising a non-rotatable massive central shaft on which a circular-cylindrical roll sleeve the sliding shoes are loadable by means of load pistons under the pressure of hydraulic fluid against the inner surface of the roll shell 15 to control the nip pressure distribution of the nip at said slipper shoes, the load pistons being

20

Several different deflection-compensated or adjusted rolls of a paper machine are already known. These rolls generally comprise a solid, stationary roll shaft and a roll shell arranged to rotate around it. Arranged between said shaft and the jacket are a series of sliding shoes acting on the inner surface 25 of the jacket and / or compression fluid chambers. Generally, nips formed by such rolls, such as press nips or calendering nips, are loaded with loading forces applied to the shaft pins of the deflection controlled roll and its counter roll.

The present invention relates to deflection-compensated or adjustable rollers comprising a series of sliding shoes, the sliding surfaces of the shoes acting on the inner surface of the roll shell and the sliding surfaces of which are at least partially hydrostatically lubricated with a sliding surface-applied pressure oil.

35

The hydrostatic load-bearing members of the zone-adjustable roll are generally known to consist of two functional parts, a sliding shoe resting on the roll shell and a load-transmitting piston 2 74525 ^. The link shoe should guide along the inner surface of the roll shell, while the opposite part of the piston, the cylinder, is located on the stationary central axis of the roll. In constructions in which the sliding shoe and the piston-cylinder form a fixed unit, the arrangement of the piston must be so loose that the piston 5 can always adapt to the position determined by the sliding shoe. The sliding shoe must also be locked against possible rotational movement and the frictional force caused by the rotational movement must be transmitted to the central axis. In the above-mentioned one-component construction, it is known from the prior art that the rotational movement of the shoe is often prevented by means of separate spacers extending from one shoe to another. The force of friction-10, in turn, is transmitted through the seal to the central shaft. The disadvantage of such solutions is the rapid wear of the seal. Structures are also known in which, in the cross-section of the roll, the sliding shoe is provided with a double piston, which structure effectively prevents the shoe from rotating, but the structure is particularly demanding in terms of manufacturing accuracies.

15

As has been shown in part above, a large number of different functions are required of said support and loading members loaded with a pressurized fluid, the integration of which into the same member has not been successfully achieved by previously known arrangements. The characteristics required of said support and load members are further listed below: - the hydrostatic lubrication of the sliding shoes and the load piston / cylinder must be adequately sealed even with varying load forces, 25 and even in the event of angular changes between the jacket and the inner part, in some solutions against lateral forces which are forces due to friction, 30 - the load shoe loading equipment must be able to act as a joint because the positions of the supported sheath and the central axle vary considerably with load forces, - the shoe pistons must provide sufficient radial force with a sufficient range of 35 - it must be possible to control the thickness of the oil film lubricating the sliding surface of the sliding shoes 3 74525 1, and - the drilling of the load-bearing pistons and the central axle of the support shoes must allow considerable radlaaliliikkeet.

5

In the previously known support and load members, the functions listed above, at least not all of them, are not carried out satisfactorily. It is therefore an object of the present invention to avoid said drawbacks and to provide a new support and slinging arrangement for sliding shoes so that the above-mentioned features can be realized.

The main object of the invention is to provide a support structure between the sliding shoe and the piston, in which the shoe can be reliably guided on the central axis without lateral forces being applied to the piston or separate connecting rods being required against rotation. It is a further object of the invention to provide such a support structure in which the cylinder and the piston can be manufactured only according to their own conditions, e.g. in terms of clearances, seals and materials.

It is a further object of the invention to provide such a sliding shoe support support arrangement in which the pivot point of the sliding shoes with respect to the load pistons is made as close as possible to the lubricated sliding surface of the sliding shoes so as to minimize the sliding turning moment.

25

It is a further object of the present invention to provide a central support arrangement for sliding shoes and their loading pistons in which compressed oil can be led from the loading space of the loading pistons to the hydrostatic lubrication spaces of the sliding shoes by a simple arrangement.

30

In order to achieve the above and later objects, the invention is essentially characterized in that said ball bearing comprises as part a lens body with a spherical bearing plate and a planar sliding surface opposite it, which lens lens allows at least a roll between the sliding shoe and the load piston, that the actual sliding shoe and / or its support shoe and the groove part of the central shaft are so arranged that the axial sides of said groove part or parts thereof form sufficiently precise guide and support surfaces and centering parts for said sliding shoes.

When using the structure according to the invention, the shoe and the piston are independent parts which can each be constructed to best suit their own function. The lens piece used in the bearing joint according to the invention acts as a member connecting the slipper and the load piston. The Ί0 construction also gives the shoe good and reliable control. Such guidance on the central shaft has not been possible in connection with the previously known relief joint structure. The above-mentioned control is achieved in such a way that the central axis of the roll preferably has a continuous axial groove, the width of which is only slightly larger than the width of the sliding shoe or its support shoe. In this case, the opposite axial sides of the sliding shoe 15 or its support shoe correspond to the sides of said groove so as to provide a preferred guide of the shoe.

The surfaces of the lens body of the invention are not substantially lightening, but are made as small as the surface pressure allows for mechanical strength. The pressure area 2 bounded by the O-ring entering the groove of the lens body, e.g. of the order of 2 cm, represents a very small part of the total force between the shoe and the piston multiplied by the oil pressure.

The invention will now be described in detail with reference to an embodiment of the invention shown in the figures of the accompanying drawing, to the details of which the invention is in no way narrowly limited.

Figure 1 schematically shows an embodiment of the invention, i.e. a tk roll 30 in axial section, forming a nip with a counter roll.

Figure 2 shows section II-II in Figure 1.

Fig. 3 shows, on a larger scale than Fig. 2, an axial vertical section of a load piston-slipper assembly applying a support and fastening arrangement according to the invention.

s 74525 1 The general structure of the zone-controlled deflection-compensated roll shown in Fig. 1, which is mainly known from the prior art, will first be described. Tela 10, e.g.

the press roll or calender roll of a paper machine, comprises a rotating cylindrical shell 11 with a fixed solid shaft 12 inside. A sufficiently large free space 13 is left between the inner surface 11 'of the shell 10 11 and the shaft 12. The shell 11 is mounted on shaft pins 12a extending the shaft 12 and 12b with bearings 13a and 13b. The end flanges 14a and 14b close the jacket 11. The roll jacket 11 is operated by means of a drive device (not shown).

Opposite the roll 10 there is a second roll 50, which rolls 10 and 50 together form, for example, a compression nip N. Between the shaft 12 and the inner surface 11 * of the casing 11, loading piston-slipper systems 20 ^ -20 ^ according to the invention are arranged. zone-adjustable and compensable to the desired, e.g. evenly distributed line pressure.

Each of said cylinders 16 is supplied with oil ducts 18 from an external bellows source (not shown) of a suitably adjustable pressure P. Each cylinder 16 has a piston 15 to which each is connected its own sliding shoe 20. The sliding shoes 20 are identical to each other and spaced as little axially as possible from each other so as to obtain a sufficiently uniform continuous load on the inner surface 11 'of the cylinder liner 11 even with high compensating forces. The shoes 20 have, for example, four hydrostatic lubrication combs 23a and 23b, between and at the edges of which there are covers 24 which form a lubricated sliding surface against the smooth inner surface 11 'of the casing 11. Lubricating oil from the pressure space 16p of the cylinder 16 is supplied to the hydrostatic lubrication chambers 23a and 23b via a support arrangement according to the invention, which will be described in more detail later.

30

The central shaft 12 has planar side surfaces 12a and 12b, which leave spaces 13a and 13b, which can be used, for example, as spaces through which the bellows fluids are led through the bores 18 of the cylinder rail 16. The dimension of the space between the central shaft 12 and the inner surface 11 'of the roll shell 11 on the side 35 of the sliding shoes 20 is denoted by S1 and on the opposite side by S2. Said dimension is smaller than dimension S2 and suitable ranges of said dimensions are <= 4 ... 10 mm and S2 ** 15 ... 30 mm.

6 74525 1 The actual sliding shoe 20 is a conventional, four-chamber, stabilizing, hydrostatic bronze shoe, each chamber 23a, 23b being provided with its own throttling nozzle 22.

5 Underneath the actual slipper 20 is a steel support shoe 25, the strength H of which is determined by the stiffness requirements. The support shoe 25 is guided laterally-large. In this way, the central shaft 12 has a uniform groove 30. This gives a good centering on the shoes 20 in both the transverse and the rotational direction. At the same time the central axle. the groove 30 is made to have a minimum width L with respect to the shoe 20, i.e. the axis 10 12 weakens as little as possible.

The groove 30 of the central shaft 12 has vertical sides 32, the upper parts 33 of which form, with a suitable small clearance, support and guide surfaces for the vertical sides 25a and 25b of the support shoe 25. The height of the support shoe 25 is denoted by H and the width by 15 L. Said dimensions H and L are generally in the range L = 150 ... 200 mm and H = 30 ... 40 mm. The distance between the upper parts 33 of the sides of the groove 32 is, for example, 0.5 mm greater than the width L of the support shoe 25, so that a good and reliable control of the support shoe is obtained.

The load cylinder 16 is a straight hole drilled in the central shaft 12, in which a cast iron plunger 15 with a sealing ring 17 is placed. The piston 15 has a channel 19a for a sliding surface 20 'of the shoe 20 for hydrostatic lubricating pressure oil. A porous bronze filter cartridge 19c is placed in the channel 19a as a safety device against dirt particles.

25

Between the cylinder 16 and the support shoe 25 there is a hinge portion of a lens body 38, the surface 39 of which is connected to the spherical surface 36 of the protruding part 35 of the piston 15, is a small-radius ball, and the surface 40 of the support shoe It is essential that the diameter Dq of the guide recess 37 in the support shoe 25 is larger than the diameter D1 of the lens body 38. In this case, the sliding shoe 20 can be positioned guided freely with respect to the piston 15 by the sides 33 of the groove 30 of the roll shell 11 and the central shaft 12, and there is no blind control with the piston 15. This prevents the side effects of a situation in which the cylinder bore 16 is slightly eccentric with respect to the guide surfaces 33 of the groove 30 or in which the cylinder bore 16 is slightly oblique. A diameter difference Dq-D ^ of about 2 mm is sufficient to eliminate the possibility of practical errors. A guide recess 37 in the support shoe 25 is required for axial positioning of the shoe 20. The recess 7 74525 1 37 in the support shoe 25 can also be oval, whereby the axial control is quite precise and at the same time the positional function described above is maintained.

The axial positioning of the shoe 20 with respect to the piston 15 takes place by means of the above-mentioned spherical surface 36,39 of the central joint of the parts 15 5 and 25. The need for positioning is caused by e.g. deflection of the central shaft 12 due to different roll loads. Due to the small radius R of the spherical surface 36.39, the frictional moment resisting the position remains relatively low. The radius R is generally in the range R = 15 ... 30 mm, preferably in the range R «20 mm.

10

The center of said radius R is preferably located on the central axis of the piston 15.

The support shoe 25 is fixed to the upper side of the piston 15 by means of screws provided with springs 28 through holes 26. The actual sliding shoe 20 is fixed with screws 21 to the planar upper side of the support shoe 25, the lower side of the sliding shoe 20 also being planar.

The oil hydrostatically lubricating the sliding surface 20 'of the sliding shoe 20 is led from the pressure space 16p of the cylinder 16 through the filter 19c to the piston 15 channel 20 but 19a and further through the bore 42 of the lens body 38 to the support shoe 25 channel 19b. 23b, to which the lens body 38 is provided with O-ring seals 41 in the annular grooves of the lens body 38 for sealing the lubricating oil to be supplied. The lens body 38 is made of steel or bronze. To secure and facilitate installation, the shoe 20 is secured to the piston 15 by two springs 27 provided with springs 28, whereby the entire assembly 15,20,25 can be easily handled as a single unit.

The sliding shoe arrangement according to the invention is intended in particular for use in connection with sliding shoes in which mainly hydrostatic lubrication is applied. Partially hydrodynamic lubrication can also be used in the sliding shoes 20, which provides e.g. the advantages of the sliding surfaces 20 with chamfers at the trailing edges, which together with the inner surface 11 'of the jacket 35 H delimit the wedge spaces where the lubricating fluid dam pressure can be created. . In this regard, reference is made to the applicant's FI patent application No. 8 74525 1 860644.

The structure described above works essentially as follows. The shaft 12 is pressed against the counter roll 50 by means of articulated bearings 5 (not shown) attached to its shaft pins 12a and 12b to load the nip N, whereby the shaft 12 also bends. To control the distribution (profile) of the nip pressure N by zone, slip-piston combinations are derived

20-20 ,, to load through the channels 18 an adjustable amount of oil pressure-1 N

those which press the pistons 15 and the sliding surfaces 10 'of the sliding shoes 20 attached thereto in the region of the nip N against the inner surface 1Γ of the roll shell 11. The sliding shoes 20 obtain their lubricating oil from the load oil and pressure of the pistons 15 so that the pressure of the lubricating oil in the spaces 23a and 23b is proportional to the load pressure of the pistons 15 and the shoes 20 attached thereto. As the shaft 12 bends due to the loading forces, the sliding shoes 20 can settle 15 according to the casing 11 and the pistons 15 according to the central shaft 12, because the pistons 15 and the shoes 20 are connected to each other by a support joint arrangement 35,38 according to the invention. The shoes 20 can also be positioned in the cross-sectional plane of the roll 10 around the ball joints 36,39 and this position is not disturbed by the sealed introduction of lubricating oil through the joints into the chambers 23a and 23b of the shoes 20.

In the following, the claims are set forth within the scope of the inventive idea defined by which the various details of the invention may vary and differ from those set forth above by way of example only.

25 30 35

Claims (5)

A guided support arrangement between the sliding shoes (20) and the load pistons (15) of a zone-adjustable roller (10), which roller (10) comprises a non-rotatable solid center shaft (12), on top of which is a rotatably stored roller sheath (11) in the form of a circular cylinder, in which between the shaft (12) and the inner surface (11 ') of the roller sheath (11) are provided several (Nst) load piston-sliding co-combinations (20 ^ -20 ^) loaded with hydraulic pressure fluid, sliding shoes (20) by conveying load pistons (15) can be loaded with a pressure of a hydraulic fluid against the inner surface (11 ') of the roller sheath (11) for checking the distribution of the nip pressure of the nip (N) at said sliding shoes (20) and which load pistons (15) are arranged at the cylinder bores (16) of the center shaft (12) or corresponding spaces, the guide arrangement between the sliding shoe (20,25) and the load piston (15) comprises a ball bearing with a relatively small bearing radius (R), characterized in that: the said ball bearing belongs to one part thereof a lens piece (38) having a spherical bearing surface (39) and a planar sliding surface (AO) thereto, which lens piece (38) permits, apart from a rotation about said spherical surface, a linear displacement between sliding shoes (20, 25) and the load piston (15) at least in the direction of the rotational plane of the roller sheath (11), that the actual sliding shoe (20) and / or its supporting shoe (25) and the spare part (30) of the central shaft (12) are arranged so that the axial sides (32) of said spool (30) or its parts (33) form sufficiently precise guide and support surfaces and centralization parts for said sliding shoes (20, 25). 1 Patent claim Support arrangement according to claim 1, characterized in that the center point of the radius (R) of said spherical bearing surface (36, 39) is located at the center axis of the load piston (15). 30 Support arrangement according to Claim 1 or 2, characterized in that the bearing groove (R) of said spherical bearing surface (36,39) is in the range R 15 to 30 mm, most preferably R 2 to 20 mm. 4. Support arrangement according to any of claims 1-3, characterized in that, through the most convenient central bore,