FI80737B - Screen plate and method for the manufacture thereof - Google Patents

Abstract

The present invention relates to a screen plate and to a method for the manufacture thereof. The screen plate according to the invention is particularly suitable for the manufacture of screening drums for the paper and cellulose industry. The screen plates/drums according to the prior art have been found to have disadvantages, which to a large extent derive from the method of manufacture currently employed, in which the aim is to machine the screen plate from one single piece. The plate wear and the relatively small open surface, which both result in a limited capacity, are some of the deficiencies that have been encountered. According to the invention the screen plate is manufactured from a base plate 1 and strips 6, which are fixed thereto and which are made from a material that has better wear resistance than the base material. In order to improve the screening efficiency, the strips 6 are arranged so as to cover the screen openings 3, the fibres reaching the opening having to turn through approximately 180 degrees, that is to say the time during which the centrifugal force acts on the fibres is maximised. <IMAGE>

Description

1 80737

Screen plate and method of making it

The present invention relates to a screen plate and in particular to a method for manufacturing a screen plate. In particular, the screen plate produced by the method according to the invention is intended for use in the manufacture of screen drums for sorting fiber suspensions in the paper and cellulose industry.

A wide variety of methods for making screen drums are known in advance. One way of dividing the screen drums used in the wood processing and paper industries into two groups is the starting material used in their manufacture. In some cases, especially in older solutions, the screen drum 15 was made of a rod, wire or similar material. For example, U.S. Patent No. 2,850,165 (A. Hesse et al.) Discloses a screen cylinder consisting of a large number of axial rods which leave screen slots spaced apart and supported in grooves at both ends so that the spacing of the rods, i.e. the width of the screen slots, can be adjusted as desired. The radial support is ensured by arranging a few support rings at regular intervals inside the rods, against which the rods are tightened by rims outside the rods. Such screen cylinders are very slow and complex and thus also expensive to manufacture and, in addition, due to the complex support structure, their weight increases unnecessarily.

Another example is the solutions of U.S. Patent Nos. 2,983,379 (H. G. Cram) and 3,561,605 (D. M. Likness), in which a drum is formed by winding either a circular or square metal wire in a spiral on substantially axial support rods. The support rods can be located either outside or inside the wire spiral and the wire spiral is attached to the support rods, for example by welding. The structure is considerably lighter than before, but still difficult and slow to manufacture. In addition, this method is poorly suited for obtaining narrow slits 5 according to the current requirements, since the dimensional accuracy requirements are currently very high.

As a further alternative, DE-A-30 15 370 (W. Musselmann) discloses a structure in which a screen drum 10 is assembled by stacking a large number of rings twisted from a wire of a certain cross-sectional shape so that a certain gap is provided between the rings by spacers, said members being relatively easy. adjust as desired. However, the manufacture of the cylinder is not particularly simple in this case either, since the drum consists of a large number of loose parts which must be assembled and tightened tightly together.

A more modern way of manufacturing screen drums is where the screen surface itself consists of a smooth planar surface that is bent substantially cylindrically in a manner appropriate to the purpose for making the screen drum. The most common method of fabricating screen plates and drums made therefrom is to perforate the drum blanks and finish them on all sides before bending the plate, allowing the holes or slits to be machined to be easily oriented and shaped, except for distortions caused by bending the plate. Extremely simplified manufacturing has resulted in the 30 screen drum consisting of a single cylindrical plate blank bent, usually machined in plate form, and which, after bending, is welded together to form a single drum.

Recently, a screen plate according to U.S. Patent No. 4,529,520 P713 / 8803 (3,80737) (Lampenlus) has become very popular among users because the production values it achieves in most cases are significantly better than medium screen plates or drums. The screen plate according to said US 5 patent is characterized in that the screen slots or holes therein are arranged in the bottom part of the grooves machined in the screen plate, the grooves and ridges creating a strong turbulence in the suspension to be screened, which facilitates the free movement of acceptable fibers in the suspension. through the openings the so-called. the accept.

Theoretically, it is possible to further improve the separation efficiency of the screen by arranging for the fiber passing through the screen opening 15 an angle of rotation greater than the 90e angle disclosed in the above-mentioned publication. In this case, the action time of the centrifugal force with which the heavier particles are separated from the fiber suspension increases and the separation efficiency correspondingly. Thus, by appropriately placing the screen opening on the bottom or side of the groove 20, the superiority of the presented solution can be further enhanced.

Of course, many other screen plates with grooved or otherwise similar surface shapes are also known, such as the solutions of U.S. Patent 2,827,169 (Cusi) or WO 87/03024 (Malm), in which the grooves are open V-shaped and have a screen opening. is ranked on the second side level of his career. In addition, both publications mention that the screen opening is located specifically in the side plane 30 downstream of the ridge. It should be noted that in the solutions according to these publications as well, the theoretical turning angle of the fiber is higher than 90 ° to W0 in solution 90® to 115® and in US solution about 135®. However, even these solutions do not provide a complete solution to the problems encountered in the sorting of fibrous material, because not only should the screen drum be capable of P713 / 8803 4 80737 maximum sorting efficiency, the drum should also maintain its efficiency for as long as possible.

However, it is a fact that all grooved or somewhat uneven screen plates / drums wear faster than smooth ones, so that their separation efficiency rapidly decreases from their theoretical initial value, because good separation efficiency is largely due to surface irregularities. Many different ways of improving the wear resistance of the screen surface 10 are known in the art, such as coating with chromium or some other harder material, whereby a thin, more wear-resistant surface is obtained on the base metal or in the surface layer. However, the chromium plating or similar coating tends to detach as a plate from the surface, exposing the base material and beginning to wear at a high rate.

A third significant shortcoming is the small open area experienced by prior art screen plates, which is largely due to the manufacturing method used. Screen plates with screen slots are made by milling a wider groove on one side of the plate that does not extend directly through the plate. At the bottom of this said groove is further milled a slit width 25 through the plate extending through the plate, the length of which in the conventional solution is only about 50-60% of the length measured from the surface of the wider slit screen plate. The reason for this is that the diameters of the circular blades used for milling are so large that the rounding of the ends shortens the length of the resulting opening 30. Of course, it would be possible to reduce the diameter of the cutter blade, but then the production of the plate would be further slowed down, because already the current blade diameter moves at the lower limits of the blade life.

The problems which led to the invention can thus be summarized in three components: wear resistance and sorting efficiency, which are clearly interdependent, as well as a factor affecting capacity, i.e. a large open area.

The screen plate according to the invention solving the above-mentioned problems is characterized in that the protrusion is a member made of a wear-resistant material, which is fixed to the surface of the plate so that a screen gap remains between the member and the surface of the plate.

10

The method of manufacturing a screen plate according to the invention is characterized in that means are attached to the surface of the plate, the distance from the surface of the plate being adjusted to the gap used in screening and said members 15 being arranged intersecting thought extensions of said openings or a plane perpendicular to the plate.

The advantages achieved by the invention are e.g. the following: 20 - the wear part, i.e. the list on the surface of the plate, which causes swirling, fluidisation, etc., is interchangeable - in some cases even the sizing of the screen is adjustable - the production of the plate is simplified because some of the work steps 25 are eliminated - the fiber turning angle is maximized, in some cases even above 180 ° - the effective surface area of the plate increases significantly compared to previous solutions 30 - the material of said wear list can be selected to be more wear-resistant than the base material.

In the following, the screen plate according to the invention and its manufacturing method will be explained in more detail with reference to the accompanying figures, of which P713 / 8803 6 80737 Fig. 1 shows a preferred embodiment of the invention, Fig. 2 shows another preferred embodiment of the invention, and Fig. 3 shows a number of other preferred embodiments.

Figure 1 shows a screen plate according to a preferred embodiment, consisting of a base plate 1, in which low grooves 2 are machined, on the bottom of which 10 screen openings, i.e. holes or slots 3, are arranged. openings 4 of greater width are milled on the accepting side, but do not extend through the entire plate, and "above", i.e. holes drilled on the side of the pulp to be treated, or slits 15 are milled, which act as screen openings and thus correspond to the size of the screen opening required for the final use of the screen. . Attached to the protrusions 5 between the grooves 2 of the screen plate is a strip 6, which is preferably made of a wear-resistant material. According to the figure, the strip 20 6 is placed on / above the holes or slots 3 at the bottom of the groove 2, so that the fiber entering the hole or slot 3 has to rotate about 180 ° before hitting the opening. Other embodiments may also be considered. For example, the bottom of the groove 2 may have 25 more rows of slots or holes in a row, the strip 6 at least partially covering at least the row of holes or slots closest to the leading edge as seen from the local flow direction of the groove mass. The fastening of the strips 6 to the base plate 1 can be performed in many different ways, welding, screwing, gluing, etc. can be used, as long as only sufficient dimensional accuracy is achieved. The list 6 itself may be of some hard metal, carbide, collected, etc. material.

As another embodiment, a solution 35 is shown in Fig. 2, which is very similar to the solution in Fig. 1, but with the exception that the sorting gap 7 is moved between the list 6: P713 / 8803 7 80737 and the base plate 1 substantially parallel to the plane of the plate 1; and between the surface of the strip 6 and the base plate 1 in Fig. 2b. Thus, the holes or slits 8 leading from below the strip 6 to the acceptor-5 side can be dimensioned considerably wider than before. The advantage of this embodiment is a large open area, because the sorting slot 7 below each strip 6 is open over the entire length of the strip 6. Another advantage is that since the gap 8 can be made directly through the entire base plate 1 10, the part of the gap required by the rounding of its ends, which affects the length of the gap, remains considerably smaller than before. These can increase the open area by up to about 50%. The only step requiring greater accuracy is to determine the distance between the strip 6 and the base plate 1 - the sorting groove 7. It can be performed, for example, as in Fig. 1 by arranging a rib-like protrusion 5 (Flg. 2a) on the surface of the base plate, on which the strip 6 is fastened, or by arranging a corresponding protrusion 9 on the lower surface of the strip 6 (Fig. 2b).

20

In the embodiment according to Figure 2b, the manufacture of the screen plate itself, i.e. the base plate 1, is very simple. All you have to do is cut - eg drill, punch, mill holes or slots in 8 plates and finish the plate. There is no need for the 25 large-scale grooves and subsequent slitting known from 25 conventional grooved screen plates, but the plate is quickly completed. Correspondingly, in the embodiment according to Fig. 2a, slitting is omitted from the work steps, because a sorting gap is created between the strip to be fastened and the base plate.

30

Figure 3 further shows a few other preferred embodiments of the screen plate according to the invention, which merely aim to show that the principles described above can be applied to the widest possible range of solutions. Figure 3a shows a solution in which a member P713 / 8803 β 80737 is added to the side of the ridge already in the plate, which increases the angle of rotation of the fiber and at least partially covers the opening in the base plate. It is, of course, clear that said member can also have a cross-sectional dimension other than a semicircle, for example a circle, triangle, square or the like in cross section 5.

Figure 3b shows how a member with a cross-section significantly different from that shown in Figures 1 and 2 is attached to the surface of the plate on the upstream side of the openings. However, the cross-section of said member can also vary considerably in this case as well, it is essential that said member at least partially covers the openings of the base plate.

Figure 3c shows how it is possible to arrange a groove on the surface of the base plate upstream of the openings so that the turbulence-generating member is attached to the groove, simply positioning it with respect to the openings and changing the cross-sectional shape of the member to be attached.

Figure 3d further shows how the base plate can have a surface according to, for example, U.S. Patent No. 2,827,169. However, in the solution according to the invention, a turbulence-inducing wear-resistant member is attached to the upstream side of the ridges, which increases the angle of rotation of the fiber, causes a much higher turbulence and enhances the separation efficiency.

30

It can be said that a large number of different solutions have been presented above for a new type of screen plate, which is characterized by two things. The turbulence-inducing member is made of a wear-resistant material, which significantly increases the service life of the 35 screen plates / drums compared to previous solutions in which an attempt was already made to increase the service life in some way P713 / 8803 9 80737. In addition, it is possible to provide said member for removal and thus replacement, whereby by replacing the wear turbulence strips, the same base plate or drum can be used many times longer than before. Another feature is that the angle of rotation of the fiber passing from the openings of the screen plate to the accepting side has been increased as much as possible, for which it is absolutely necessary that the turbulence-causing members at least partially cover the openings in the screen plate 10.

Finally, it should be noted that the above examples and embodiments are by no means intended to limit the invention to the disclosed solutions, but rather to show that the invention has a large number of significantly different solutions, the features of which are set out in the appended claims. alone determine the scope of our invention and its scope. It should also be borne in mind that, although our invention is called a screen plate, the solutions we present relate in a similar manner to a screen drum or other non-planar solution made of said plate.

P713 / 8803

Claims (5)

10 80737 1. A screen plate consisting mainly of the material to be screened, e.g. a turbulence-inducing surface solution consisting of substantially parallel protrusions arranged on the surface of the plate and openings extending through the plate, each turbulence-causing protrusion (6) being positioned so as to at least intersect the openings / openings cooperating with the respective protrusion 10 3, 8) a plane perpendicular to the plate passing through the edge of the protrusion (6) but leaving a flow gap (7) between itself and the surface of the plate (1), characterized in that the protrusion 15 is an abrasion resistant member (6) attached on the surface of the plate (1) so that a screen gap (7) remains between the surface of the member (6) and the plate (1). Screen plate according to Claim 1, characterized in that the member (6) is fastened to a protrusion (5) on the surface of the plate (1), the height of which protrusion substantially corresponds to the width of the sieve slot (7). Screen plate according to Claim 1, characterized in that a protrusion (9) is arranged on the lower surface of the element (6), the height of which corresponds to the width of the screen slot (7). 4. A method of manufacturing a screen sheet, the method comprising cutting holes, holes, slits or the like in the sheet through which acceptable fibrous material is passed to the accepting side of the screen sheet, thereby providing turbulence-inducing members on the upstream side of the unsorted pulp surface. P713EN.RE1 / PRO07 11 80737 means for attaching to the surface of the plate means whose distance from the surface of the plate is adjusted to the size of the gap to be used in the screening and that said members are positioned so as to intersect said the intended extensions of the openings or the intended plane perpendicular to the plate passing through said openings 5. A method of manufacturing a screen plate according to claim 4, characterized in that strips are attached to the surface of the plate on the protrusions between the screen openings, which are arranged to extend at least partially over the imaginary extensions of the screen openings so that the fiber has to rotate more than 90 °. P713EN.RE1 / PR07 i2 80737 Patervtkrav