NO812243L - DEVELOPMENT FILES DEVICE. - Google Patents

Description

In the case of dewatering machines, particularly within the paper industry, where dewatering is common in the wet part of the paper machine/development work has constantly been aimed at achieving a more efficient dewatering procedure...'

A typical example of suitable machinery is the so-called plan-; wire machine, in which a dewatering box with negative pressure is used to suck the water from the combined wire and material sheet in the form of a wet web.......

i A problem arising from a procedure of this type

consists in that the material that is dewatered is collected in the form of a suspension on the wire, and when the combination frémmates we-, you in the machine, it tends to compress or tangle. This entanglement makes remote in-! gene of the water.

These problems increase when you consider that the pressure is exerted at different places along the paper machine, especially in the wet section. The constantly acting negative pressure leads to a constant negative pulse against the wet web, which further tends to entanglement of the combination consisting of the suspension and the wire. The consequence is a reduction in efficiency, as the process progresses.

Various attempts have been made to increase the dewatering efficiency. Thus, a higher negative pressure has been used, either as a constantly greater suction force or a progressively increasing suction force, when filtration increases during the dewatering process. Many different blades, sheets and dewatering devices have been used in many different forms to improve the dewatering process with negative pressure and negative pulse. These experiments include a reversal of the traditional blade formers and of ledge-shaped foils with "different shapes.

The construction with positive pulses has been developed to a certain extent, particularly with regard to table rollers. This procedure;

involves bringing the wet wire into engagement with table-

the rollers that push the track up and form a possible positive pulse. However, this effect is impossible to control and is limited to a direct relationship between speed and roller diameter. The latter cannot be controlled to provide a more efficient dewatering process, especially in connection with the combination of foils and more negative pressure. There is thus room for a better drainage system. in which the benefits of the foils' design are used for negative pulsing and for sucking water away from the wet web, as well as for allowing a positive pulse to act against the web to loosen tangled sheets and the wire, as well as to improve the dewatering negative pulse courses , which is carried out after the positive

pulsation. Naturally, the intended system must be suitable for the application of negative and positive pulses along the dewatering machine, especially when it concerns the wet section of the paper machine. Naturally, it is also desirable to have a simple and cheap construction, for example an improved design with a single foil, which can be releasably mounted in a stationary position on an existing machine, for example a plane wire machine.

With regard to what has been stated above, the primary purpose of the present invention is to provide a foil which is suitable for installation in a dewatering machine, e.g. a paper machine. The foil is designed in such a way that it can form at least one positive pulse to the wet path that passes over a wear surface on the foil. If desired, the blade can have a further part with such a design that facilitates the application of a negative pulse against the wet web to provide dewatering.

One purpose of the invention is to provide such a foil of the above-mentioned type, which has a unitary construction and which is arranged for mounting on a common, well-known type of machine, for example a plane wire machine. The foil is arranged to be mounted in a row of foils that exhibit aligned wear surfaces that are passed by a wire and a sheet over this in the form of a wet path. The blade is arranged to be mounted so that a suitable negative pressure source for providing negative pressure for dewatering purposes. in

The foil according to the invention is designed with a front edge part with a tapering shape, so that it decreases upwards

i in the direction of movement towards the path to facilitate the direction of the water towards the path for positive pulsation purposes. For example, the taper can amount to approx. an angle of 10°C~against it ! upper wear surface, which is usually located in an essentially horizontal position when the foil is mounted on the main rail. The foil according to the invention can also be designed in such a way near its rear edge that this shape facilitates the application of a lower pulse to help remove the water from the wet web. According to one embodiment, this can be achieved by means of a ledge, to provide a drainage near the rear edge for the water to be sucked through and fed

res to a suitable removal chute after the blade has been shifted in the open path movement.

One purpose of the invention is thus to provide a foil with foil angles which act to exert a positive as well as a negative pulse against the wire and the wet sheet web in a paper machine during the propagation process. The positive pulse first seeks to loosen the tangled sheet and the web, which is then more effectively dewatered when exposed to the negative pulse. In general, the positive pulse, which is exercised against the wet track, enables a more efficient dewatering with the subsequent dewatering element. The foil is arranged for mounting on a dewatering box for a conventional planwire paper machine for the purpose of removing the water from the sheet. It is particularly suitable for fitting into the wet part of the paper machine, especially with units where negative pressure is applied.

A chamfer near the front edge of the foil according to the invention causes the water to be forced into the underside of the wet web in the pressure nip between the web and the tapering surface, so that it is pushed up and into and through the web, while this is held down by the subsequent negative pressure unit.

One purpose of the invention is to provide a combination blade, which with a positive angle tapers close to the

at the leading edge for the purpose of forming a positive pulse and then with a ledge, near the trailing edge to facilitate the formation of a subsequent negative pulse when the blade is mounted in a device that increases the negative pressure, thereby achieving a more effective drainage or liquid-removing construction.

• I

One purpose of the invention is to provide a foil construction which forms positive pulses in certain areas including a first foil for a dewatering element on a flat wire machine in combination with suction boxes, in combination with suction boxes and in combination with flat boxes. Furthermore, the foil construction according to the invention can extend to include the leading edge of some stationary devices which are arranged below the forming member, for example foils and/or deflectors.

In summary, the invention provides a liquid-removing blade or foil that forms positive pulses that facilitate the removal of the liquid from a wet track. The blade is provided with a device so that it can be releasably mounted to the dewatering machinery. An upper wear surface of the foil is in a position with engagement in the wet web that passes over it. The blade has a leading edge with a shape which directs the liquid on the underside of the web towards it and thus exerts a positive pulse against the wet web in an upward direction away from the surface of the blade to dissolve the web and then facilitate the removal of liquid therefrom . The blade includes a trailing edge portion spaced from the trailing blade to form a drain opening for the liquid to be removed from the wet web after it has passed over the wear surface of the blade. The blade can be shaped on the upper side near its rear edge which seeks to draw liquid from the web and exert a negative pulse against it to facilitate the removal of liquid from the web which was previously subjected to a positive pulse.

In what follows, the invention will be explained in more detail with reference to the attached drawings in which fig. 1 vi-j see a partial ground plan of the wet end of a paper machine with a series of blades mounted on it,

fig. 2 shows a partial side view taken along the line 2-2 i

in

fig. 1, and

in fig. 3 shows a side view of a sheet according to the invention, removed from the paper machine according to fig. 1 and "2".""'

The upper side of part of the wet paper in the flat wire machine 20 is shown in fig. 1. Fig. 2 is a side view of part of the machine 20 with a series of separate, aligned dewatering blades which are releasably mounted on the machine in the usual manner. Of the blades shown, the blade 22 is designed according to the invention and is arranged between two ordinary dewatering blades 24. A slot 26 is formed between each pair of blades to exert a negative pressure against the upper surface of the machine 20. Appropriate end caps 28 are arranged to seal the ends, so that the slots 26 are located in the central part of the machine 20. The wet material path passes over the middle part of the machine.

The web is available in the form of a sheet of material that must be dewatered on a movable foil. The sheet was originally in the form of a slurry which is compacted during movement

when subjected to normal gravity and additional vacuum forces applied during processing. A conventional vacuum source (not shown) is connected to the machine, so that a negative pressure prevails in each slit 26. In this way, water is sucked through the slits into a normal suction box, tube or similar construction, where air is drawn through the path and absorbs water, after which the mixture of water and air is later separated in a well-known manner.

When the web passes over the upper surface of the blade in the direction shown by the arrow in fig. 2, it comes into contact with the upper wear surface part. of the leaves and exposed to vacuum, which combination draws air oq water from the web through i

slot 26 for collection and removal.

The blades: 124 are conventional and of the ledge type with a front horizontal wear part 30, which ends with a ledge 32 in connection with recessed surfaces 34. The vertical distance between the surfaces 30 and 34 forms an enlarged area for vacuum, to which the web is exposed for by communication with the slits 26 and thus increases the efficiency with regard to the removal of water from the web when this is moved over the blade. This vacuum effect is commonly known as adding a negative pulse to the path. This action also tends to compact and cause sheeting of the mass on the wirenj which makes further a<y>traction of water more difficult. To loosen or shake up the tangled wet web, the blade 22 is used.

As shown in fig. 3, the blade 22 comprises a part 36 extending downwards from the underside 38 in order to be able to engage securely with corresponding surfaces on the machine. A suitable locking rod 40 for engagement with the blade 22 in order to ensure locking is shown in fig. 2. This type of construction is common, for the blade 24, which also includes a corresponding downwardly extending part 42 for mounting on the machine in engagement with a locking rod 44. Thus, the blades 24 and 24 are mutually interchangeable and can be set on the machine with a desired design and setting for maximum efficiency during the dewatering process.

The blade 22 includes a leading edge for an initial contact with the moving web. The lower part 46 on the front edge is chamfered downwards and in the direction of movement to facilitate the removal of the water which is sucked through the adjacent slit 26 under the influence of negative pressure. The upper part 48 of the front edge is chamfered upwards in the direction of movement to form a nip with the horizontally moving wet web. The upwardly chamfered part 48 ends in a horizontal wear surface 50, which engages with the underside of the track. The combination of the underside of the track, the beveled front end part 48 and the wear surface 50 form a nip that collects the water from the track and. pushes the water up through this and loosens the tangled mass on the wire, so that water can then be drawn off the wet track more easily and more efficiently. This effect is described as the exercise of a positive pulse towards the track.

The path then passes the landing 52 in connection with the recessed surface 54 near the rear edge 56. The recessed part forms a space for applying negative pressure in the 'sahuné manner' as described with reference to corresponding parts on the blade 24. Thus the path is exposed to a negative pulse and the detached path, which was exposed to a previous positive pulse, is dewatered in a more efficient way. The water is carried away through the subsequent slit 26 by means of the longitudinally chamfered surface 58. A suitable gutter. 60 is provided in the rear surface 58 to facilitate the fitting of the end covers 62, which seal the ends of the paper machine, so that the negative pressure is concentrated to the open central part of the gap 26, as the wet web passes over it.

The setting of blade 22 in relation to blade 24 is determined as desired. It may form the first, the last or the intermediate leaf, as shown. Likewise can. the number of leaves 22 in relation to the number of leaves 24

is selected depending on the desired pulse effect in the system.

During operation, the wet web is advanced in the direction of the arrow in fig. 2 over the blades 24, 22 and engages the wear part 30 on the blade 24 and the wear part 50 on the blade 22. The slot 26 is placed under vacuum to suck air through the wet web and pass the mixture of air and water through the slots for collection on the normal manner. When the wet web approaches the wear surface 50 of the blade 22, a pressure nip will form on its underside at the chamfered front edge part 44. Water that is sucked through the wet web and into the lower part of the web is brought into engagement with this pressure nip and is fed up through the wet web to loosen the tangled sheet.

The detached sheet then passes over the wear surface 50 to a position just before the recess 54. The negative pressure in the recess 54 sucks water from the wet web and the water is removed through the gap 26 at the rear end of the blade 22 under the influence of the chamfered surface 58 as well. The suction efficiency of the web is enhanced as a result of the positive pulse before the web is subjected to suction under the formation of a negative pulse for dewatering the web. The web, which is still relatively loose, can then be subjected to processing of the usual type, for example the blade 24, which only exerts a negative pulse. A positive pulse can be introduced by means of a blade 22 at any time during manufacture in order to loosen the tangled suspension forming the sheet on the wire.

It has proven to be effective to design the chamfered front end part 48, so that it forms an angle of approx. 10° with the main horizontal wear part 50. This obtains the desired angle in the press clip and promotes the direction of the water up through the path as a positive pulsating influence. The lower part of the front edge 46 is chamfered downwards in a direction away from the direction of movement of the web and forms an angle of approx. 30 in relation to the vertical plane, so that water and air that were previously sucked away from the track during the dewatering process are directed downwards for an efficient collection of this.

The blades 22 and 24 are interchangeable and detachable so that they can be replaced or interchanged at any desired time. Moreover, they can be produced from ordinary plastic or "nylon" in a manner known per se. In this way, the above-mentioned advantages are achieved in a very efficient manner.

Claims (10)

1. Positively pulsed dewatering blade (22) for promoting the removal of liquid from a wet web of material, characterized by means on the blade for its releasable mounting on the dewatering machine (20), with a space (26) in its vicinity for the removal of removed water therethrough , an upper wear surface (30, 50) 'on' the blade (22) in a position for engagement with the wet path passing over it, a front edge of the blade (22) with such a shape that it tends to direct the liquid towards the web to exert a positive pulse up against the wet web and away from the upper wear surface (30, 50) of the blade (22) for the purpose of subsequently promoting removal of the liquid, and a trailing edge arranged to lead to a dewatering space for the removal of liquid that is carried away from the wet path when this has passed over the wear surface of the blade (22) (30, 50). 2. Dewatering blade according to claim 1, characterized in that the part closest to the rear edge has such a shape that it will guide the liquid from the web and exert a negative pulse against it to facilitate the removal of liquid from the web when this has previously been exposed to the influence of the positive pulse. 3. Dewatering blade according to claim 1, characterized in that the blade is mounted in the wet section of a paper machine for dewatering the wet web. 4. Dewatering blade according to claim 3, characterized in that the blade (22) is mounted in the suction box of a plane wire machine for removing water from the wet web in the form of a sheet and a wire. 5. Dewatering blade according to claim 1, characterized in that the blade is arranged for mounting as one blade (22) in a series of blades (24) in the direction of movement of the wet path, the blade (22) being arranged to provide at least one positive pulse and at least one of the other blades (24) is arranged to form at least one negative pulse, the alternating pulses being arranged to act against the wet web which produces an effect involving dewatering of the web. 6. Dewatering blade according to claim 1, characterized in that the dewatering machine comprises a vacuum source for applying vacuum to the blade and that a recess near this to suck liquid from the wet web and dewater it. 7. Dewatering blade according to claim 1, characterized in that the edge lying near its front part is chamfered (48) and extends at an angle to the wet web in the direction of movement of this to form a pressure nip for liquid on the underside of the web so that the liquid is forced into and pushed up into the path. 8. Dewatering blade according to claim 7, characterized in that the dewatering machine comprises a vacuum source, which is connected to the blade (22), so that when the liquid is pushed up near the rear edge of the blade (22) and into the path, this is held down against negative pressure acting on the path. 9. Dewatering blade according to claim 7, characterized in that the chamfered part (48) near the front edge is designed with an angle of 10° in relation to the upper wear surface (5)) of the blade (22). 10. Dewatering blade according to claim 7, characterized in that the second part near the front edge is chamfered downwards and in the direction of movement of the path to facilitate the removal of the liquid that is not fed into the press nip, the first part of the press nip being found between the second part and the wet track.