Arrangement in an adjustable roller bearing for lateral guidance of running webs

An adjustable roller bearing for lateral guidance of travelling webs, e.g. a paper wire, comprises a bearing casing that is slidably mounted in a bearing foundation by the aid of members projecting diametrically from the bearing casing and bearing foundation and being in engagement with each other as well as encased by in hydraulic or pneumatic bellows which act to displace the bearing casing. The projecting members are provided with cooperating guide grooves and rollers respectively. The guide grooves are diametrically outside the contact faces of their associated roller, and have faces which in cross section follow a circular curve having the roller center as its center. Between each of these faces and the adjacent roller contact face there is a lining one end of which is adapted to the circular shape, whereas the other side, facing the roller contact face, is planar and forms a contact face for the corresponding roller.

The present invention relates to an arrangement in an adjustable roller 
bearing for lateral guidance of traveling webs, e.g. a paper wire in a 
paper machine, said roller bearing comprising a bearing casing that is 
slidably mounted in a bearing foundation by the aid of members projecting 
diametrically from said bearing casing and bearing foundation, being in 
engagement with each other and being encased in hydraulic or pneumatic 
bellows means acting as displacement means for the bearing casing, said 
projecting members being provided with cooperating lateral grooves and 
rollers respectively. 
Such an adjustable roller bearing for lateral guidance of running webs is 
known from NO-PS No. 120 104. An adjustable roller bearing of this kind 
has a compact and sturdy design, comprises displacement bearings 
(roller-guide grooves) showing low friction, and provides a positive and 
linear guide movement. The movable parts of said roller bearing are 
provided inside said bellows means completely protected against external 
influence. 
The bearing casing and the bearing foundation with associated members are 
usually made from cast steel. When such adjustable bearings were used it 
was found that the rollers cause wear of the cast steel in the guide 
grooves cooperating with said rollers due to incident moment loads. It is 
an object of the invention to provide linings, e.g. manufactured from 
spring steel, between said rollers and cooperating groove faces, designed 
in such a manner that moment loads are balanced and the wear is reduced. 
According to the invention an arrangement in an adjustable roller bearing 
of the kind mentioned above is thus proposed, said arrangement being 
characterized by the fact that said guide grooves are formed diametrically 
outside the contact surface of associated rollers which grooves in cross 
section conform to circular curves having the roller center as their 
center and by the fact that between each each of these faces and the 
adjacent roller contact face a lining is provided one side of which is 
adapted to said circular curve shape, whereas its other side facing the 
roller contact face is planar and forms a contact face for the roller. 
In case of moment loads said linings will be able to move a little, i.e. 
carry out a rotary motion as seen in cross section. Thus, the moment load 
is balanced and wear is considerably reduced. 
The two linings in each guide groove may suitably be connected to each 
other. In an especially advantageous embodiment said two linings in each 
guide groove are provided as parts of an integral body. By using such an 
integral lining body in each guide groove the entire guide groove cross 
section may advantageously follow a circular curve, said integral body 
being provided with a corresponding outer surface. 
Said linings are preferably kept in place by resilient means so that said 
linings are able to carry out the desired minor swinging/rotary motions.

The adjustable roller bearing shown in FIG. 1 mainly comprises a bearing 
foundation 1 consisting of a base 2 from which rise supporting members 3 
and 4. Furthermore, the roller bearing comprises a bearing casing 5. Said 
bearing casing 5 is composed of a lower shell 7 and an upper shell 6 which 
together form a spherical casing of a top bearing provided on the roller 
top not shown. 
Lower shell 7 is at each side provided with a flange 8,9 respectively. The 
bearing foundation is provided with corresponding flanges 10,11 
respectively, on its supporting members 3,4. Between the flanges 8,10 and 
9,11, respectively, facing each other a bellows means 12, 13 is clamped. 
Each bellows means 12, 13 is connected to a pressure fluid source in a 
manner not shown. Reference is made to the above mentioned NO-PS No. 120 
104 showing details of clamping bellows means between the flanges. 
A projection 14 extends from flange 8. Another projection 15 extends from 
flange 10. Said projections 14,15 engage each other, see FIGS. 2 and 3, 
and projection 14 is provided with two guide grooves 16,17, whereas the 
fork shaped projection 15 is provided with two rollers 18,19. Each roller 
18,19 is mounted on projection 15 by the aid of a bolt 20,21. 
As will appear especially from FIG. 2, guide groove 16 has faces 22, 23 
that are curved in cross section. The curvature follows circular curves 
having the center in the center of roller 18. Between roller 18 and the 
faces 22, 23 of guide groove 16, extending diametrically outside said 
roller, a lining 24, 25 is provided. Each of said linings 24,25 is an 
elongated, i.e. strip shaped, member one side of which is curved in 
correspondence with the curvature of the contacting face 22, 23 of groove 
16, whereas the other side is planar and forms a contact face for roller 
18. 
Each lining 24, 25 of this kind is clamped by the aid of a resilient 
clamping connection. An example of such a connection is shown in FIG. 5. 
In lining 24 a threaded bore 26 is provided and a threaded sleeve 27 is 
threaded into said bore. In projection 14 a bore 28 is provided, which 
forms an extension of an expanded bore 29. A screw 30 is threaded into 
sleeve 27 and a helical spring 31 is provided between the head of said 
screw 30 and the annular bottom of bore 29. Bore 28 has a larger diameter 
than screw 30. This clamping connection thus permits a certain degree of 
movement between projection 14 and lining 24. Bore 29 is closed by a 
plastic plug 32. Lining 25 is mounted accordingly. 
Groove 17 is provided with corresponding linings for cooperation with 
roller 19. In FIG. 1 projections 14,15 are shown on only one side of the 
bearing. Corresponding projections with associated guide grooves and 
rollers are obviously provided on the other side of the bearing, inside 
bellows means 13, as well. 
Instead of two separate linings, such as linings 24, 25, the linings may 
obviously be constructed as parts of an integral body. Such a possible 
embodiment is shown in FIG. 4. The same reference numbers are used for 
corresponding parts, said reference numbers being marked. Guide groove 33 
is here formed in projection 14' with a full guide face cross section, 
i.e. the guide groove cross section follows a circular curve on its entire 
extension. Correspondingly, lining 34 is formed with a corresponding 
outside face 35. Lining 33 is thus constructed as a homogeneous body, 
showing an approximately U-shaped cross section with roller 19' entering 
the U-shape, as shown in FIG. 4. 
Generally, casting steel is used for manufacturing the bearing casing and 
bearing foundation, as well as for the projections on said components. In 
this connection it will be advantageous to use spring steel for 
manufacturing the linings. It will be understood that the faces having a 
circular arc-shaped cross section in the guide grooves may be machined in 
a simple manner and the same goes for the curved face on the lining.