FI78751B - OSCILLERINGSMEKANISM FOER STRAOLROERET I EN PAPPERSMASKIN. - Google Patents

Description

78751 ^ Paper machine nozzle oscillation mechanism

Oscilleringsmekanism för stralröret i en pappersmaskin 5

The invention relates to an oscillating mechanism for a paper machine nozzle, through which water jets are directed to the surface of the paper machine to be cleaned, such as a wire or felt, and which jet is connected to a is connected to said oscillating mechanism by which the rotational movement of the motor is converted into a reciprocating oscillating movement of the reciprocating part of the nozzle, the oscillating mechanism comprising a transverse bearing which is pivotally mounted on a non-rotating oscillating-20 part, if The rolling ring has an inner annular cam which is in tension with the groove of said cross recessed screw so that the point of intersection remains in a certain plane set through the axis of rotation of the transverse screw while said rolling ring and its annular cam can rotate under the control of said bearing.

For cleaning paper machine fabrics such as wires and / or felts, spray tubes are used that extend transversely across the entire width of the fabric. These jet tubes have a series of nozzle holes through which high pressure water jets are usually applied to the outer surface of the tissue to clean the tissue. The pressure of the washing water is high, usually about 20-50 bar.

The nozzle tube is oscillated back and forth in its longitudinal direction in order to ensure that the washing effect is not wilted, but is spread evenly over the entire width of the fabric. In general, the oscillation length is equal to the distribution of the 35 washing water spray nozzles along the length of the nozzle tube.

Said nozzle tubes are generally placed in connection with paper machine wires or slight return runs. The nozzle tubes will be located in very difficult conditions and will have to operate under the contaminating effects of moisture, splash water and pulp. Thus, open mechanisms cannot be used to oscillate the spray tubes, as their operation would be disturbed due to impurities and moisture. Indeed, several oscillating requirements are imposed on the oscillating mechanisms of the orifice tubes, the simultaneous fulfillment of which has not been satisfactorily succeeded in all respects with the known oscillating devices. These requirements are 10 - reliability despite harsh conditions, - steady speed and rapid change of direction, and - small size of the device so that it can often fit in very cramped spaces' 15 Several different nozzle oscillation mechanisms are already known, including various crank mechanisms achieve a smooth reciprocating motion. It is also known to use various chain mechanisms that extend transversely across the width of the tissue to be cleaned. However, chain mechanisms are susceptible to interference 20, are difficult to protect, and take up relatively large space. Also known are those based on the change of the direction of rotation of the electric motor. mechanisms which, however, have the disadvantage that repeated and frequent implementation of reversal reliably produces difficulties. Various rack-and-pinion mechanisms are also known in the art, which, however, take up a relatively large space and are difficult to protect.

In these oscillating mechanisms, in addition to the rotary motor, pneumatic diaphragm motors or fluidized-cylinder cylinders are used as the drive motors, which, however, have the disadvantage of achieving smooth movement and the risk of hydraulic fluid leakage and sufficiently fast reversal.

In jet tube operation, it is known to use a transverse groove shaft, in connection with which the groove 35 is a boat follower, in connection with the groove 35, in order to convert the rotational movement into an oscillating axial movement. A problem with this mechanism is the wear of the slider and the consequent entrapment of the device, which causes strong jets of water to be applied to a narrow area of tissue, resulting in damage to expensive tissues.

It is known from the prior art to use ball screws for converting rotary motion into axial motion in jet tube operation, for which reference is made by way of example to U.S. Pat. No. 4,087,320. However, the ball screws are complicated in structure and, at least for the time being, still quite expensive components.

With regard to the state of the art most closely related to the present invention, reference is made to the journal article "Ant, Antriebstechnik 17 (1978) No. 7/8 pp. 341-342", which discloses a certain type of Phillips screw mechanism for converting a rotating movement 10 into a rectilinear movement. It is a particular object of the present invention to further develop the mechanism described in the above-mentioned magazine article so that it is better suited than the known mechanism for the purpose of the invention, i.e. oscillating the jet tube in very cramped conditions and harsh conditions.

15

The general object of the invention is to avoid the above-mentioned drawbacks and to provide a new oscillation mechanism which takes up a smaller space and has a better operational reliability.

In order to achieve the above and later objects, the invention is mainly characterized in that the transverse screw is slidably mounted on the part to which the pivoting member of the rolling ring is fixed to allow rotational and axial movement.

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 shows an overview of a jet tube device according to the invention placed in connection with the tissue to be cleaned.

Figure 2 shows a central axial section of a mechanism according to the invention by which the rotational movement is directed into an oscillating axial movement 35 along the length of the nozzle tube.

Fig. 3 shows a vertical cross section ΪΙΙ-ΙΙΙ in Fig. 2.

4 78751 1 Figure 4 shows a cross-section of a rolling ring and a ring cam used in the mechanism according to the invention.

Figure 5 shows a plan view of the groove of a cross recessed screw used in the mechanism according to the invention.

According to Figure 1, the spray tube 20 extends in the transverse direction B of the wire or felt 15 to be cleaned over the entire width of the fabric 15. The jet tube 20 is oscillated by a drive unit 10 which includes an electric motor 10A rotating in one direction, e.g. a short-circuit motor, the rotational movement of which is converted into a reciprocating (arrow A) oscillation motion of the jet tube 20 by a mechanism to be described in more detail. On the upper side of the spray tube 20 there are nozzles 30 in an even distribution, through which strong needle-like water jets S are directed onto the outer and lower surface 15 of the fabric 15. The nozzle tube 20 is attached to the upper side of the housing beam 40 by handles 44. The housing beam 40 is supported by horizontal rollers 42 in the forks of the vertical beams 41 and 46 which support the beam 40 on its underside so that the beam 40 and the attached shutter tube 20 can be oscillated by the drive unit 10. -20 to 45 vertical axes. The rotational movement of the motor 10A is converted by the mechanism according to the invention into an axial reciprocating oscillation movement of the arm 23. The outer end of the arm 23 is vertically attached to the flanges 43 on the vertical side of the beam 40. The reciprocating oscillation distance L provided by the drive unit 10 is preferably equal to the mutual distribution of the nozzles 25 30.

Figure 1 shows a guide roll 13 of a fabric 15, e.g. a forming wire, supported on horizontal beams 47 of a paper machine frame structure by means of vertical beams 48 and mounted on said vertical beam 48 by bearings 14. In connection with the vertical beams 48 there is also a scraper 53 of the roll 13. The fabric 15 is, for example, the return run of the forming machine forming wire.

Wash water is introduced into the spray pipe 50 through the tube 20 in the direction of arrow W. Shower pipe 20 is a water flow through in such a way that the jet pipe 20. The use-side end 35 at the opposite end of the winding 51, through which the view of those len-W of the wash water flow through, which will also take place removal of dirt. Inside the nozzle 20 there are cleaning brushes known per se, 5 78751 1 which are accessible by a handwheel 52 located on the treatment side of the machine.

A preferred embodiment of the oscillating device 5 according to the invention will now be described with reference to Figures 2,3,4 and 5. The motor 10A of the drive 10 drives a Phillips screw 21 which is fixed to the shaft of the motor 10A by a wedge 17. At its motor end, the screw 21 is mounted by a bearing 18 on the drive body flange 19. The drive is housed inside a tube 16 provided with a service hatch 39. The drive 10 according to the invention 10 is characterized in that the diameter D of the housing 16 is sufficiently small so that the drive 10 can be placed in a very cramped space and can be effectively protected against dirt and moisture. An essential component of the drive device 10 is the aforementioned cross groove screw 21 having a cross groove 22. The shape of the groove 22 is shown in plane shown in Figure 5. The groove 22 has rounded end portions 22A and 22B with (R 1, R 2). In cooperation with the cross groove 22 there is a rolling ring 36, the ring cam 37 of which is in position R in contact with the cross groove 22 of the shaft 21 to convert the rotational movement of the shaft 20 21 into a reciprocating oscillating movement of the shaft 23 (arrow A). and the axial distance between 22B.

For the above purpose, a rolling ring 36 is connected to a pivot ring 34 by means of a bearing 35. Said pivot ring 34 is in turn fixed to the fork 31 by pins 32 and their bearings 33. The fork 31 is in turn screwed to the slider 25, which in turn forms a cross groove screw 21. The body 25 is connected to the body tube 16 via its projection 25a 30 so that rotation of the body 25 is prevented. For this purpose, the protruding portion 25a of the body 25 has, as shown in Fig. 3, an axial groove 27 in which a fixed slider 28 fixed to the inner wall of the body tube 16 is slid, fixed to the body tube 16 by screws 29. The body 25 is attached to the end 23 of the tube arm 23 as described above, a spray pipe 20 is used via the flanges 43 and the beam 40.

6 78751 1 The interaction of the cross groove 22 of the screw 21 and the rolling ring 36 will be described below. The rolling ring 36 is supported by its bearing 35, which transmits axial forces, so that the rolling ring 36 does not perform planetary motion, but rotates only under the effect of frictional forces transmitted from the rupture point R so that between the ring cam 37 and the side 22a or 22b of the cross groove 22 R remains in the axial median plane of the screw 21. In the situation according to Fig. 2, the annular cam 37 of the rolling ring 36 moves the fork 31 and the parts 25, 24 attached thereto via the bearing 35, its pivot ring 34, pins 32 and bearing 33, and 23 in Fig. 2 to the left 10 the oscillation distance L of the arm 23 comes at the right end 22B of the cross groove 22. The end 22B guides the annular cam 37 to a second, oppositely sloping return groove, thereby changing the direction of movement of the aforementioned portions until the right end position shown in Figure 2 is retracted by the groove 15R between the groove 22 side 22a and the right side 37A of the annular cam 37. guided by the end 22A, there is again a transition to the portion of the cross groove 22 having the opposite pitch.

Since the rolling ring 36 does not make a planetary motion as is the case with the above.

20 in the reference "Antriebstechnik", in which the center of the corresponding rolling ring moves in a circular path, the mechanism according to the invention requires substantially less space in the radial direction, i.e. the dimension D becomes smaller than the corresponding dimension of the known structure.

In the mechanism according to the invention, the rolling ring 36 rotates in its bearing 35 only without rotating the frictional forces between the rupture point R so that the circumferential speed of the annular cam 37 is approximately equal to the circumferential speed of the transverse screw 21 using it. 37A and 37B alternately over the entire circumference so that the annular cam 37 has a large wear surface and wears evenly. For this reason, the mechanism described above is wear-resistant and reliable.

The mechanism according to the invention is also advantageous in that it can easily be arranged to make the slider 25 and the fork 31 and the arm 23 attached to it non-rotatable. Another advantage is that the lubrication of the mechanism can be arranged easily and so that the lubrication interval is quite long.

Fig. 4 shows a preferred embodiment of the invention in which a rolling ring 36 simultaneously forms an inner ring of a ball bearing and this ring has a one-piece annular cam 37 with inclined mating surfaces 37A and 37B corresponding to vertical sides 22a and 5 of the transverse groove 22 having a corresponding inclination. 22b.

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

10 15 20 25 30 35

Claims (3)

8 78751 ^ Claims A paper machine nozzle oscillating mechanism, through which nozzles (20) water jets (S) are applied to the surface to be cleaned of a paper machine fabric (15) such as a wire or felt, and which nozzle (20) is connected to a drive device (10) for arranging nozzle (20). in the direction of its length, preferably in the transverse direction of the fabric (15) to be cleaned, reciprocating and the drive (10) comprising a rotation motor (10A) whose shaft is connected to said oscillating mechanism by changing the rotational movement of the motor (Ι0Α). ) for a reciprocating oscillating movement, the oscillating mechanism comprising an axially non-displaceably bearing transverse screw (21), the distance (L) between the ends (22A and 22B) of the transverse groove (22) determining the oscillating distance 15 (L), the mechanism further comprising a rolling ring (36) is a bearing mounted on the outer circumference by transmitting axial forces (35) to a portion (34) pivotally mounted on a non-rotatable oscillating portion (23), the rolling ring (36) having an inner annular cam (37) in rush with the groove (22) of said cross recessed screw (21) such that the rupture point (R) remains in a certain plane set through the axis of rotation of the transverse screw (21) while said pivot ring (36) and its annular cam (37) are allowed to rotate under the control of said bearing (35) while the pivot ring (36) ) for axial movement, characterized in that the cross recessed screw (21) is slidably mounted on the part to which the pivot member of the rolling ring (36) is fixed to allow rotational and axial movement. A mechanism according to claim 1, characterized in that a pipe arm (23) is attached to the opposite end of the fork (31) of said slider (25), inside which said cross recessed screw (21) extends and that said pipe arm (23) or a part attached thereto a nozzle (20) or a block beam (40) or the like is attached. 35 A mechanism according to claim 1 or 2, characterized in that said slider (25) or its protruding part (25a) has an axial groove (27) in which a fixed slider (28) fixed to the mechanism body tube (16) slides. or the like. 5 15 20 25 30 35 ίο 78751 ^ Patentkrav