US3557276A

US3557276A - Method of making a fine screen

Info

Publication number: US3557276A
Application number: US720872A
Authority: US
Inventors: Charles J Williams
Original assignee: Erie Development Co
Current assignee: Erie Development Co
Priority date: 1966-12-07
Filing date: 1968-04-12
Publication date: 1971-01-19
Anticipated expiration: 1988-01-19

Abstract

A METHOD FOR MAKING SCREENING PANELS FROM HARDENABLE SYNTHETIC ORGANIC RESINOUS MATERIAL BY INTRODUCING THE LIQUID RESINOUS MATERIAL INTO A MOLD HAVING A PLURALITY OF INTERCONNECTING GROOVES PROVIDING TRUNCATED PEAKS THEREBETWEEN IN AN AMOUNT IN EXCESS OF THAT REQUIRED TO FILL THE GROOVES, PLACING A RESILIENT COVERING SHEET OVER THE FILLED MOLD AND THEN A RIGID PLANE COVER ON THE RESILIENT SHEET. THE COVER AND SHEET ARE SECURED TO THE MOLD SO THAT THE TRUNCATED PEAKS PRESS INTO THE RESILIENT SHEET THUS REMOVING EXCESS RESINOUS MATERIAL FROM THE TOPS OF THE PEAKS AND EXUDING EXCESS RESINOUS MATERIAL FROM THE MOLD. THE RESINOUS MATERIAL IS THEN ALLOWED TO SET AND AFTER DISASSEMBLING THE COVER AND SHEET THE SCREENING PANEL IS REMOVED FROM THE MOLD IN A SUBSTANTIALLY FLASH FREE CONDITION.

Description

Jan J. W LL ;METHOD OF MAKING A FINE SCREEN Original Filed Dec. 7, 1966 IN VEN TOR.

United States Patent 3,557,276 METHOD OF MAKING A FINE SCREEN Charles J. Williams, Aurora, Minn., assignor to Erie Development Company, Cleveland, Ohio, a corporation of Delaware Original application Dec. 7, 1966, Ser. No. 599,931, now Patent No. 3,483,976, dated Dec. 16, 1969. Divided and this application Apr. 12, 1968, Ser. No. 720,872 Int. Cl. B29d 27/00 US. Cl. 264316 3 Claims ABSTRACT OF THE DISCLOSURE A method for making screening panels from hardenable synthetic organic resinous material by introducing the liquid resinous material into a mold having a plurality of interconnecting grooves providing truncated peaks therebetween in an amount in excess of that required to fill the grooves, placing a resilient covering sheet over the filled mold and then a rigid plane cover on the resilient sheet. The cover and sheet are secured to the mold so that the truncated peaks press into the resilient sheet thus removing excess resinous material from the tops of the peaks and exuding excess resinous material from the mold. The resinous material is then allowed to set and after disassembling the cover and sheet the screening panel is removed from the mold in a substantially flash free condition.

This application is a division of my" parent US. patent application Ser. No. 599,931 filed Dec. 7, 1966- now Pat. No. 3,483,976 dated Dec. 15, 1969.

This invention relates to the screening art, and is concerned with the provision of an improved fixed fine screen of the type disclosed in US. Pat. No. 2,916,142, Fontein, dated Dec. 8, 1959.

Said type of fine screen is characterized by an inclined screening deckflat, or curved-composed of parallel spaced rod-like members which are disposed transversely to the direction of flow thereover of a slurry of a material to be screened. In screens of this category the spacesstyled slotsbetween said rod-like members may-and usually dohave positive relief. The size of solid particles passing through these slots is not more than one-half the width of said slots, and hence the rod-like members are spaced in a dimension predetermined with regard to the critical size of screeningor, split--to be effected by said screen. In carrying out a screening operation on a screen of this type a slurry of a material to be screened is flowed, at a relatively high velocity, over and substantially parallel to the screening deck in a direction transverse to the long axis of said slots. That is to say, the direction of the solid particles (in such slurry) with respect to said slots is such that the particles are traveling substantially parallel to the screen surface and those the diameters of which are not more than one-half the width of said slots are diverted (by the hydraulic action of the liquid of the slurry flowing through the slots) to a direction perpendicular to the screen surface and are transported by such liquid through said slots.

The aforesaid screens are styled stationary to distinguish them from screens which are vibrated or oscillated during their use,

The performance of fine screens of the aforesaid type depends on a large extent on the sharpness of the rod-like members or bars which form the slots. Inasmuch as materials normally screened are abrasive, the screens that are presently in use rapidly become less effective as the leading edges of the bars become dulled through wear.

Also, characteristically these screens must be made such that the openings or slots must be larger at the 3,557,276 Patented Jan. 19, 1971 bottom than they are at the top. This is termed slots with relief. In presently used screens the slot relief is obtained by the use of parallel wedge-shaped bars. Fabrication of presently used screens consists of laboriously welding or otherwise fastening individual wedge-shaped bars to support members or ribs.

The ability of screens of the aforesaid type to differentiate between particles of different sizes in a uniform manner depends on the uniformity of slot width. This characteristic becomes increasingly more important as the slot width is decreased. Because of the inherent difficulty of jigging a wedge-sectioned rod or wire in fabrication, variation in slot width is inevitable and increases percentage wise as the slot opening is decreased. As a result, sharpness of separation decreases as variation in slot opening increases.

According to the present invention inobvious improvements in a fine screen of the aforesaid stationary type are realized by forming the screening deck thereof of a moldable synthetic organic material, which term I employ herein as including synthetic organic elastomeric materials and plastics. The mode of fabricating the screening deck is that of molding from a liquid as by liquid casting, pressure forming, injection casting or like procedure, or by suitably calendering a material in readily impressionable-"intermediate-state.

Amongst elastomeric materials for use in forming the fine screen of the present invention are the following: neoprene, butyl rubber, butadiene-styrene rubber and urethane rubbers; fiuorocarbons; silicones. Amongst plastics for this use are the following: various resinous compounds such as nylon, polystyrene, polyethers, alkyd resins, melamine resins, phenolic resins.

The fine screen panel of the present invention consists esentially of a unitary slab or body having on one side thereof a plane screening surface, said slab comprising an array of interconnecting screening bars and support bars. The spaced screening bars are parallel to each other, and the spaced support bars-parallel to each otherpreferably are disposed at an angle of less than 90 to said screening bars. Each of said screening bars and support bars has, in cross-section, the shape of a truncated pyramid or wedge, the bases of the pyramids lying in a single plane and providing the aforesaid screening surface.

The invention will now be described in greater particularity and with reference to the appended drawing, in which FIG. 1 is a perspective view of apparatus for carrying out the process of the present invention;

FIG. 2 is a perspective view of a fragment of a screening deck (hereinafter referred to as a panel) embodying features of the present invention; and

FIG. 3 is a side elevational view of the fragment shown in FIG. 1, in section.

THE MOLD The mold M was composed of a lower plate (or, mold cavity) 11 and cooperating upper plate 12. Lower plate 11 was a piece of free-machining steel 1.25 inches in thickness by 16.0 inches square. The steel piece was machined top and bottom to flat parallel surfaces. On the top side of lower plate 11 a first series of 72 similar parallel grooves 15 were machined in the surface, the grooves being 0.15 inch in depth and spaced apart so as to leave an uncut portion of the surface, between each two adjacent grooves, 0.07 inch in width. At the top the grooves were 0.09 inch in width. These dimensions provide a positive draft angle of At a 45 angle to the grooves of said first series there were cut into the piece a second series of 36 parallel grooves 20 of the same cross-section as were the grooves of said first series, the spacing between adjacent grooves O of said second series being 0.354 inch. Thus, the interconnecting first and second series of grooves and form separate truncated peaks therebetween which are formed so that the tops thereof lie in a plane slightly above the plane of the periphery of the metallic mold 11, i.e. of the order of magnitude of .001". A third series of 4 grooves 25, having a depth of 0.2 inch and a width of 0.2 inch, were cut around the periphery of the grooved portion of the plate to define a 12 inch square.

The first series of grooves, the second series of grooves and the third series of grooves were in a form complemental to a symmetrical truncated pyramid their sides having the same angle of inclination.

In the four corners of plate 11, bolt holes 26 having a diameter of inch were drilled.

Upper plate (cover) 12 was a piece of steel 16 inches square and 1.25 inches thick, machined to have flat parallel upper and lower surfaces. Bolt holes 27 matching holes 26 were drilled in plate 12.

In addition to the above-described components of the mold, there was provided a sheet 27 of Teflon (tetrafluoroethylene), having a thickness of one-thirty-second of an inch, which Teflon sheet was of a size just covering the aforesaid 12-inch square but having at each of its four corners an ear projection 30 having therein an aperture 31 matching

bolt holes

26 and 27.

Bolts 34 were provided for securing together the mold cavity 11, Teflon sheet 28, and upper plate 12.

The upper surface of mold cavity 11 presented a network of interconnecting grooves, surrounded by a lower (deeper) peripheral groove, which interconnecting grooves isolated the mold cavity surface into a multitude of parallelogram-shaped islands of metal.

It is noted, at this point, that the purpose of the Teflon sheet was to allow the parallelogram-shaped islands in the mold surface to protrude up into the Teflon a distance on the order of magnitude of .001. This protrusion resulted in the production of screen castings with flash-free parallelogram-shaped openings.

THE MOLDING MIXTURE In this specific example the starting material was a room temperature-curing urethane (Flexane 85, liquid) consisting of an isocyanate resin in liquid form and a liquid hardening agent. The two liquid components were mixed together at room temperature and thereupon were ready for use.

THE CASTING PROCEDURE The surfaces of the mold cavity were sprayed with a liquid mold release compound, to prevent the elastomer from sticking, and was allowed to dry.

Thereupon, the aforesaid two-part urethane rubber mixture was poured into the mold cavity and spread so that there was an excess of the mixture over that amount required to completely fill the interconnecting grooves. The Teflon sheet 28 was then positioned over the filled mold cavity 11, the upper plate (i.e., cover) 12 was placed on top of the Teflon sheet, and the three parts were bolted together by means of bolts 34. The excess resinous material is thus removed from the tops of the truncated peaks to eliminate substantiall all flash adjacent the peaks, as previously mentioned and the excess resinous material will be exuded around the edges of the metallic mold.

The liquid urethane mixture set in approximately one hour, and hardened over night to the point where demolding was feasible. The so-produced screen panel 35 was easily stripped from the open mold.

The completed panel was a square slab 12 inches on a side, and comprised 72 parallel wedge-shaped screening bars 37, supported by 32 diagonally disposed supporting bars 39 and by a somewhat larger dimensioned peripheral supporting rib 40.

A stationary fine screening deck was fabricated by fixing the above-described screen panel to a support characterized by an array of parallel arcuate metal support rods, spaced apart on two inch centers, and joined at top and bottom by transverse beam members. The same was then associated with conventional adjustable means for positioning the curved screening deck at a suitable angle for use in screening an aqueous slurry or pulp of finely divided solid oxidic iron ore particles of various sizes.

The above-described screening deck was used in classifying an aqueous slurry of finely sudbivided particles of iron oxide ore material varying in sizes between mesh and 10 microns. A sharp split was realized. I

Molded or cast screens of the sort above described have an advantage over welded metal screens in that the cant or attitude of the wedge-shaped bar can be more accurately controlled. The top surface of each wedge-shaped screening bar should be parallel to the screening surface so that the screen panel can be reversed with respect to the direction of slurry flow.

A screen panel embodying principles of this invention can be constructed such that in its use a controlled amount of screening bar flutter or movement will result which movement minimizes the tendency for the slots to become blinded or plugged. The flutter or movement of the bars can be controlled by selecting the appropriate stiffness of the wedge section, the distance between the supports or ribs, and the method for inducing flutter. The flutter may be induced by slurry flow, by sound waves, by machine vibration, or by mechanical shock.

A screen panel made in accordance with this invention can be used as a flat screening surface or as a curved screening surface merely by substitution of spaced metal support rods which are straight or curved to any radius. Furthermmore, by the useof semi-flexible support rods, the curvature of the screen can be varied from straight to any desired curvature while the screen is in operation. This feature allows an additional means of performance control a slurry characteristics change.

Another unique feature of a screen panel made under this invention utilizing elastomers consists in the fact that the panel can be made so that the width of the screen opening is variable. The variation is obtained by stretching the panel in a direction parallel to the screening slots. In this manner, the Width of the slots is controllably adjustable.

In the manufacture of stationary fine screens heretofore the parallel-wedge-shaped bars were fastened to the support bars by welding each individual joint which resulted in an extremely high fabrication cost. An outstandingly unique feature of the present method resides in the fact that as the simple casting is made all of the intersections (of screening bars with support bars) are formed simultaneously and automatically. The forming of the joints is made possible by making a draft angle on the support bars so that the cross section of the support bars is the same as that of the wedge-shaped screening bars.

The removal of the casting from the mold is facilitated by the fact that the screening bars and the support ribs are in the same plane and all interconnecting members have a positive draft. In the traditional method of fabricating fine stationary screens the screening bars were welded on top of the support bars, and hence the two sets of bars lay in different planes. The mold grooves having been cut 'with care, the screening bars were unvarying in straightness and in cross-sectional dimensions, and their spacing was exact. The individual panels were repeatedly duplicated (in the same mold) with no variation in any measurement. The exactness of these dimensions and of this spacing and the uniformity of panels could not be duplicated by the most painstaking welding of individual meal bars to metal support members. Notwithstanding this superiority, the cost of. manufacturing the screening panels was very significant- 1y less than was the cost of manufacturing a similar metal screening panel.

The chief advantage of the cast elastomeric screens of the present invention is that they are made of a material that outwears steel (tradiational material for this type of screen) by a factor of -100 times, and outwears natural rubber by a factor of 2-5 times.

The efliciency with which fine stationary screens operate depends largely on the sharpness of screening openings. By the present method an extremely sharp screening opening is produced as the metal parallelogram-shaped openings on the surface of the mold protrude up into the Teflon. Furthermore, as Teflon has memory" and returns to normal shape when the pressure is removed, it is usable over and over again.

It is to be appreciated that the data of the above specific example are not limitative of the scope of the present invention. Thus, the screening panels have been cast using Du Ponts Adiprene, Thiokols Solithane and Devcons Flexane, all of which are urethane liquid elastomer. This description is not intended to be restrictive to the materials just enumerated, since other plastics and elastomers could be used as well.

Nor are the specific angles between screening bars and support bars critical. While the invention has been illustrated through disposing first and second series of bars at approxmiately 45 to each other, it is a fact that any angle between about 90 and about 10 will be found to be operable, depending upon the particular slurry involved and other variables.

Moreover, the particular widths of the screening bars and the particular sizes of the screen openings or slots are matters of engineering and experience.

Production of the screens may be accomplished by pressure forming, liquid casting, and injecting casting. With increased draft angle on the mold and the mold actually on a roller, the screen material can be manufactured in continuous rolls (i.e., by continuous casting techniques).

I claim:

1. A method of making a synthetic organic resinous screening panel which comprises introducing a liquid hardenable synthetic organic resinous material into the cavity of a metallic mold having a network of interconnecting grooves which form a plurality of separate truncated peaks, the tops of which lie in a plane slightly above the the plane of the periphery of the metallic mold, in an amount in excess of that required to completely fill the interconnecting grooves, placing a resilient covering sheet over the filled mold, placing a rigid plane cover over the resilient sheet securing the cover and sheet to the metallic mold thus compressing the tops of the truncated peaks into the resilient sheet whereby the excess resinous material will be removed from the tops of the truncated peaks to eliminate substantially all flash adjacent the peaks and the excess resinous material will be exuded around the edges of the metallic mold, allowing the resinuous material to set and harden, removing the rigid cover and resilient sheet from the mold and finally removing the synthetic organic resinous screening panel from the mold.

2. A method as claimed in claim 1 wherein the liquid resinous material is composed essentially of a room temperature-curing isocyanate resin in liquid form and a liquid hardening agent therefor.

3. A method as claimed in claim 1 wherein the resilient covering sheet is composed of Teflon.

References Cited UNITED STATES PATENTS 1,911,765 5/1933 Matthews et al. 264-3l6X 2,341,499 2/1944 Cunningham 264313X 2,712,150 7/1955 Marsch 264316 3,201,136 8/1965 Harrison et al. 277-198 ROBERT F. WHITE, Primary Examiner J. R. HALL, Assistant Examiner