Protection tiles for scroll conveyor flights

Abstract

A scroll conveyor tile protection or any other material subject to wear with a weldable support and a wear resistant insert, not necessary weldable. The support is fit with a flat surface and shoulder allowing for precise positioning of tile on a scroll flight to be protected. At least one opening, preferably at its center, allows for insertion and assembly of a complementary shaped insert. The unit setting up on the scroll flight and the contact between the flight faces and the unit faces allows for creating a dove tail locking system. Welding of the support permanently insures locking of the system and insert being maintained without being otherwise fixed beyond this mechanical clamping.

Claims

1. A wear-resistant tile for attachment to a scroll flight of a rotor, comprising: a support part attachable to the scroll flight, having a front face and a back face, and a profiled opening passing entirely through the front and back faces; and an insert having one, profiled portion fit within and retained mechanically to the support part by mating of said profiles through the opening of the support part, and an other portion defining a primary wear-resistant surface, wherein the support part has upper and lower regions with respective front and back surfaces; the upper region of the support part has a profiled front surface defining an upper portion of the opening, including an undercut, and a profiled back surface; the lower region defines a lower, ledge portion of the opening; the one portion of the insert has a back upper surface that fits within the upper portion of the opening and includes a projecting surface that fits within the undercut of the support part, and a lower portion including a bottom surface that mates with the ledge portion of the lower portion of the opening; whereby when said bottom surface is mated with said ledge portion, said undercut mechanically retains the projecting surface within the support part.

2. The wear-resistant tile according to claim 1, wherein said one portion is an integral, finger-like extension from said other portion.

3. The wear-resistant tile according to claim 1, wherein the other portion is a plate with a front face defining said primary wear-resistant surface, said face having opposed top and bottom spanning a height, and opposed sides spanning a width; and said one portion projects downwardly from the plate with a width less than the width of the front face.

4. The wear-resistant tile according to claim 1, wherein the support part has a profiled front surface defining the opening, including an undercut, and a profiled back surface; and the one portion of the insert has a back surface that fits within the opening and includes a projecting surface that fits within the undercut of the support part.

5. The wear-resistant tile according to claim 1, wherein the ledge inclines upwardly from the back surface to the front surface of the lower region; and the bottom surface inclines downwardly from the front to the back surfaces of said one portion the insert; whereby when said bottom surface is mated with said ledge, said undercut and said ledge mechanically retain the insert at both the upper and lower portions of the opening.

6. The wear-resistant tile according to claim 1, wherein the support part has at least one groove-like surface and the insert has a complementary shape that can be fit in the groove-like surface.

7. The wear-resistant tile of claim 1, wherein a plurality of said wear-resistant tiles are provided at the circumferential edge of a scroll flight of a rotor, with each respective support part fixed to the flight and each insert retained only mechanically to a support part.

8. A conveying device having a rotating scroll flight with circumferentially attached wear-resistant tiles, wherein each tile comprises a support part fixed to the scroll flight and defining a profiled opening; and an insert having one portion fits within and is retained only mechanically to the support part through the opening of the support part and another portion defining a primary wear-resistant surface; wherein the support part has a front face and a back face, with the profiled opening passing entirely through the front and back faces; and the one portion of the insert is profiled to fit within and be retained only mechanically to the support part by mating of said profiles through the opening of the support part, wherein the support part has upper and lower regions attached to the flight, with respective front and back surfaces; the back surface of the upper region is offset from the back surface of the lower region; the offset is defined by a shoulder aligned within the opening of the support part; the upper region of the support part has a profiled front surface defining an upper portion of the opening, including an undercut, and a profiled back surface; the lower region defines a lower, ledge portion of the opening; the one portion of the insert has a back upper surface that fits within the upper portion of the opening and includes a projecting surface that fits within the undercut of the support part, and a lower portion including a bottom surface that mates with the ledge portion of the lower portion of the opening; and said shoulder is attached to the circumferential edge of the flight and the bottom of the one portion of the insert is flush with the front of the flight such that said bottom surface is mated with said ledge portion and said undercut mechanically retains the projecting surface within the support part.

9. The conveying device according to claim 8, wherein the support part is welded to the flight.

10. The conveying device according to claim 8, wherein the support part has a profiled front surface defining the opening, including an undercut, and a profiled back surface; the one portion of the insert has a back surface that fits within the opening and includes a projecting surface that fits within the undercut of the support part.

11. The conveying device according to claim 8, wherein the ledge portion inclines upwardly from the back surface to the front surface of the lower region; and the bottom surface inclines downwardly from the front to the back surfaces of said one portion the insert; whereby when said bottom surface is mated with said ledge portion, said undercut and said ledge mechanically retain the insert at both the upper and lower portions of the opening.

12. The conveying device according to claim 8, wherein the support part has at least one groove-like surface and the insert has a complementary rise that fits in the groove-like surface.

13. A conveying device having a rotating scroll flight with circumferentially attached wear-resistant tiles, wherein each tile comprises a support part fixed to the scroll flight and defining a profiled opening; and an insert having one portion fits within and is retained only mechanically to the support part through the opening of the support part and another portion defining a primary wear-resistant surface; wherein the support part has a front face and a back face, with the profiled opening passing entirely through the front and back faces; and the one portion of the insert is profiled to fit within and be retained only mechanically to the support part by mating of said profiles through the opening of the support part, wherein said one portion of the insert is locked mechanically to the support part through a dovetail connection with the support part and a mechanical retention of the other portion against the flight by the support part.

14. A wear-resistant tile for attachment to a scroll flight of a rotor, comprising: a support part attachable to the scroll flight, having a front face, a back face, and upper, lower, and central portions, with the central portion defining a profiled opening passing entirely through the front and back faces; and an insert having a front face defining a primary wear-resistant surface, a back face, and upper, lower, and central portions, with the central portion including a profiled surface at the back face that fits within and is mechanically retained to the support part by mating of said profiles through the opening of the support part, wherein when the insert fits within and is retained mechanically to the support part, the lower portion of the support part at the back face and the lower portion of the insert at the back face are coplanar.

15. The wear-resistant tile according to claim 14, wherein an upper edge of the lower portion of the support part defines a portion of the profiled surface of the opening in the support part that is angled upwardly from back face to front face; the lower portion of the insert defines a bottom surface that is angled upwardly from back face to front face; and when the insert fits within and is retained mechanically to the support part, such that the support part at the back face and the lower portion of the insert at the back face are coplanar, the angled upper edge of the lower portion of the support part bears against the angled bottom surface of the insert.

16. The wear-resistant tile according to claim 14, wherein a region of the upper portion of the support part defines a downward facing undercut between the back face to front face; the profiled surface at the back of the central portion of the insert defines a projection that is complementary to the undercut of the support part; and when the insert fits within the support part, such that the support part at the back face and the lower portion of the insert at the back face are coplanar, the projection on the insert interlocks with the undercut on the support part to retain the insert within the support part only mechanically.

17. A conveying device having a rotating scroll flight with circumferentially attached wear-resistant tiles, comprising: a support part attached to the scroll flight, having a front face, a back face, and upper, lower, and central portions, with the central portion defining a profiled opening passing entirely through the front and back faces; an insert having a front face defining a primary wear-resistant surface, a back face, and upper, lower, and central portions, with the central portion including a profiled surface at the back face that is mechanically mated with the profile of the opening on the support part; wherein the upper back portion of the insert is in coplanar contact with the upper front portion of the support part; and wherein the lower back portion of the support part and the lower back portion of the insert are in coplanar contact with the scroll flight; whereby the support part is retained only mechanically to the scroll flight.

18. The conveying device according to claim 17, wherein an upper edge of the lower portion of the support part defines a portion of the profiled surface of the opening in the support part that is angled upwardly from back face to front face; the lower portion of the insert defines a bottom surface that is angled upwardly from back face to front face; and the angled upper edge of the lower portion of the support part bears against the angled bottom surface of the insert.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is now described in accordance with the attached drawings, where

(2) FIG. 1 is a layout of tiles on a scroll conveyor flight according to the invention,

(3) FIG. 2 is a front view of scroll flight with 5 protection tiles according to the invention applied,

(4) FIGS. 3-5 are front, left and rear views of the tile support according to one embodiment of the invention,

(5) FIGS. 6-8 are front, left and rear views of the insert,

(6) FIGS. 9-10 are section views of a protection tile according to the invention in intermediate assembly position for support and insert,

(7) FIG. 11 is a section view for a protection tile according to the invention assembled and welded on a scroll conveyor flight,

(8) FIG. 12 is a perspective view of a protection tile according to the invention assembled and welded on a scroll conveyor flight.

DETAILED DESCRIPTION

(9) A centrifuge using the invention is illustrated in FIG. 1. The centrifuge 5 is composed of a cylindrical/conical bowl 1 and a conveyor scroll 2 in rotation around the same axis. The bowl 1 and the conveyor scroll 2 are driven in rotation at slightly different speeds generating a relative speed between bowl and scroll called a conveying speed. The scroll is generally comprised of a drum 2 and a flight 3 extending radially between drum 2 and bowl 1. Protection tiles 4 are deposited side by side on the exterior flight edge. The solid/liquid mixture to be separated is introduced to the bowl 1 by means of a feed tube, not shown. The product is driven at the speed of bowl 1 and, under centrifugal force the densest particles of the product are pressed against the interior wall of bowl 1. The scroll conveyor 2, due to its relative rotation movement transports the solid particles called sediment, towards the bowl cone head.

(10) As illustrated in FIG. 2, protection tiles 4 fixed side by side on the flight 3 allow for protection of the flight 3 from generally abrasive friction from sediment and add to lifetime of scroll conveyor 2.

(11) The support 6 according to the invention shown in FIGS. 3-5 has a front face 7A and 7B interrupted by a subsidence 8 defined by surfaces 18 and 19. The rear face of support 6 is comprised of two plane faces 13 and 14 offset and forming a shoulder 17. The lateral surfaces 20 and 21 are plane and form an angle which the tiles can set in, as illustrated in FIG. 2. A profiled opening 23 limited by surfaces 9, 11, 12, 25 and 26 is achieved in this embodiment of the invention in the center of support 6. Surfaces 11 and 12 form a sharp undercut angle and are connected via a radius comprising an upper corner 10. Support 6 is generally obtained by a process of precise molding with the object of obtaining exterior and interior forms to allow for assembly of the insert 41.

(12) The insert 41 according to the invention shown in FIGS. 6-8 is comprised of a plate-like upper portion 47 and at least one finger 46 completely connected and defining central and lower profiled portions of the insert. Lateral surfaces 44 and 45 are plane and form an angle which the tiles can set in, as illustrated in FIG. 2. Plate 47 is limited by surfaces 27, 36, 37, 44, and 45 and comprises the active part of the protection tile since the friction of the product to be treated is mainly exerted onto the surface 27. The at least one finger 46 has surfaces 33, 34, and 35 in the central portion of the insert and surfaces 28, 29,30, and 31 in the lower portion of the insert. Overall the finger 46 is limited by surfaces 28-35, 42 and 43 and insures the insertion of insert into support 6. The shape of the finger 46 is close to that of the dove tail locking system with upper and lower corners 40 and 39. Surfaces 31 and 32 form opening 48 needed for assembly. Insert 41 is generally obtained by a process of precise molding with the object of obtaining exterior and interior forms to allow for the assembly with the support 6.

(13) The assembly of protection tile 4 onto the conveyor scroll 3 is achieved via the following steps. As shown in FIG. 9 and following arrow direction M1, insert 41 is introduced in support 6 by engaging lower corner 39 first in opening 23 of support 6 and by inclining insert 41 so as to form an angle with faces 27 and 7A. As shown in FIGS. 10 and 11, insert 41 is then progressively and simultaneously pivoted and moved following arrows direction M2 and M3 until complete engagement of the upper corner 40 of insert 41 into the complementary lodging 10 of the support 6 is achieved. Then this unit is positioned on flight 3 of scroll 2. Curved shoulder surface 17 and plane surface 13 of support 6 are respectively put in contact with exterior upper surface 53 and the front face 52 of scroll flight 3. The surface 52 then completes the dovetail locking system obtained by surfaces 29, 30, 33 and 35 of insert 41 and surfaces 9, 11 and 12 of support 6. The support is then fixed on the flight 3 generally by welding at angles 51 and 50 formed respectively by surfaces 14 and 53 and surfaces 24 and 52. This insures the assembly clamping and the insert 41 is being maintained without other means of fixation than this mechanical clamping. Dimensions of the two parts are such that the surface 30 of the insert 41 is generally off center towards the rear in relationship to surface 13. Surfaces 29 and 9 form a sharp angle with face 52 of flight 3; the pressure exerted by surface 52 on face 30 tends to push insert 41 towards the top as face 9 slips on face 29. By constraining the assembly in this way, any gap in the dove tail locking system is eliminated and efficient clamping is insured.

(14) Under these conditions, one can see that surfaces 36 and 7A are in contact, insuring adequate resting face for insert 41 on support 6 and allowing the protection tile to support axial load exerted by the product on the friction surface 27.

(15) The width of finger 46 is slightly less than the width of the opening 23. Existing gaps between surfaces 43 and 26 and surfaces 42 and 25 are limited but sufficient to allow for assembly described above. Friction of the product to be transported, on surface 27 generates ortho-radial forces on insert 41. Contact between surfaces 43 and 26 or between surfaces 42 and 25, depending on scroll rotation direction, allows insert 41 to support these forces.

(16) Finally, the dove tail locking system and especially the contact between male corner 40 of the insert 41 and female corner 10 of the support 6, allows the insert 41 to support centrifugation forces.

(17) It can thus be appreciated that the wear-resistant tile for attachment to a scroll flight of a rotor, comprises a support part 6 attachable to the scroll flight, having a front face 7A, 7B and a back face 13, 14, and a profiled opening 23 passing entirely through the front and back faces. An insert 41 has one, lower profiled portion 46 fit within and retained only mechanically to the support part by mating of the profiles through the opening of the support part, and another portion 27 defining a primary wear-resistant surface. As shown in FIG. 9, the support part has upper 56, lower 58, and central 60 portions, with the central portion defining the profiled opening 23 passing entirely through the front and back faces. As shown in FIG. 7, the back face of the insert has upper 62, lower 64, and central 66 portions, with the central portion including a profiled surface that fits within and is mechanically retained to the support part by mating of the profiles through the opening 23 of the support part.

(18) Preferably, as shown in FIG. 11, when the insert fits within and is retained mechanically to the support part, the lower portion 58 of the support part at the back face 13 and the lower portion 64 of the insert at the back face 30 are coplanar. An upper edge surface or ledge 9 of the lower portion of the support is angled upwardly from back face to front face, and the lower portion of the insert defines a bottom surface 29 that is angled upwardly from back face to front face. When the insert fits within and is retained only mechanically to the support part, such that the support part at the back face and the lower portion of the insert at the back face are coplanar, the angled upper edge 9 of the lower portion of the support part bears against the angled bottom surface 29 of the insert.

(19) The downwardly facing undercut at 10, 11, and 12 in a region between the back face and the front face of the support part, mates with the upwardly oriented projection 40 at the back of the central portion 66 of the insert, which has a profile that is complementary to the undercut of the support part. When the insert fits within and is retained mechanically to the support part, such that the support part at the back face and the lower portion of the insert at the back face are coplanar, the projection on the insert interlocks with the undercut on the support part.

(20) During operation, the product to be transported could possibly pass through spaces between support 6 and insert 41 without causing harm to tile resistance. If this intrusion of product cannot be tolerated, an appropriate resin can be used to fill the gaps.

(21) In another embodiment than the one shown in FIGS. 3-8, the support 6 is fixed on the flight 3 by means of glue, screws or rivets instead of weld.

(22) In another embodiment than the one shown in FIGS. 3-8, the flight surface used to complete the dove tail locking system may be the outer surface 53 or the rear surface 54.

(23) In another embodiment than the one shown in FIGS. 3-8, the opening 23 of support 6 and the finger 46 of insert 41 may be duplicated and differently positioned, for instance on both side of the parts instead of in their centers. The support may have two symmetrical openings equally spaced from its median plan which the insert comprising similar symmetrical fingers may lodge into. The openings and fingers form complementary nature suffices to ensure assembling and clamping of the system according to the above described principle.

(24) The invention is not limited to the embodiments in the drawings but as explained above in the range of the following claims.