Sorting screen for sorting material and rotor body for such a sorting screen

Abstract

A sorting screen for sorting material comprises a row of rotatable, driven shafts mutually spaced in a conveying direction. Each shaft extends transversally to said conveying direction and carries carrying a row of radially extending rotor bodies for intermittently urging material on the sorting screen upward and in conveying direction. The rotor bodies of each of said rows are mutually spaced in longitudinal direction of the respective shaft by spacers. Each spacer is a tubular spacer and each rotor body is provided with at least a recess or a number of projections retaining a respective end face of a respective tubular spacer.

Claims

1. A rotor body for a sorting screen for sorting material, the screen comprising a row of rotatable, driven shafts mutually spaced in a conveying direction and each extending transversally to said conveying direction, said shafts each carrying a row of radially extending ones of the rotor body for intermittently urging material on the screen upward and in the conveying direction, the rotor bodies of each of said rows being mutually spaced in a longitudinal direction of the respective shaft by tubular spacers retained between side faces of adjacent rotor bodies; the rotor body having an outer circumference having a number of radial projections and intermediate recessed portions and a central passage for receiving a shaft and means for causing the rotor body to be entrained with rotation of the shaft; wherein each rotor body side face is provided with at least a plurality of recesses or a plurality of a number of projections each for retaining a respective end face of a respective one of the tubular spacers; and wherein at least one of said recesses or of said numbers of projections is arranged for retaining an end face of a tubular spacer of a first diameter and at least another one of said recesses or of said numbers of projections is arranged for retaining an end face of a tubular spacer of a second diameter different from said first diameter.

2. A rotor body according to claim 1, wherein the rotor body is made of a plastic or elastomeric material.

3. A rotor body according to claim 1, the rotor body having an outer circumference with a plurality of radial projections circumferentially distributed around a central axis of rotation and projecting radially outwardly from the axis of rotation relative to intermediate recessed portions of the outer circumference.

4. A rotor body for a sorting screen for sorting material, the screen comprising a row of rotatable, driven shafts mutually spaced in a conveying direction and each extending transversally to said conveying direction, said shafts each carrying a row of radially extending ones of the rotor body for intermittently urging material on the screen upward and in the conveying direction, the rotor bodies of each of said rows being mutually spaced in a longitudinal direction of the respective shaft by tubular spacers retained between side faces of adjacent rotor bodies; the rotor body having an outer circumference having a number of radial projections and intermediate recessed portions and a central passage for receiving a shaft and means for causing the rotor body to be entrained with rotation of the shaft; wherein each rotor body side face is provided with at least one recess formed by a circular groove.

5. A rotor body according to claim 4, wherein each rotor body side face comprises at least one further circular groove concentric with said circular groove, said circular grooves being of mutually different diameters.

6. A rotor body according to claim 5, wherein each rotor body side face comprises three of said circular grooves, said grooves having different diameters.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic top view of a part of an example of a sorting screen according to the invention; and

(2) FIGS. 2A, 2b and 2C are a front view, a cross-sectional view and a perspective view, respectively, of a rotor body according to the invention.

DETAILED DESCRIPTION

(3) First, an example of a sorting screen 1 as shown in FIG. 1 is described. The sorting screen 1 is equipped with a row of rotatable shafts 2 mutually spaced in a conveying direction 18 and drivable in a common sense of rotation. Each shaft 2 extends transversally to the conveying direction 18. For driving rotation of the shafts 2, the shafts are coupled in a manner known per se to a motor via a drive train. Each of the shafts 2 carries a row of radially projecting rotor bodies 3 for intermittently urging material on the sorting screen conveyor upward and in conveying direction 18 when the shafts 2 are driven for rotation in a sense in which the upper parts of the rotor bodies 3 move with a directional component in the conveying direction 18. The rotor bodies 3 of each of the rows are mutually spaced in longitudinal direction 19 of the respective shaft 2. In operation, the circumference of each rotor body 3 moves rotationally along a rotary trajectory and the rotary trajectories of the rotor bodies 3 carried by each of the shafts 2 project between rotary trajectories of the rotor bodies 3 carried. by a neighboring one of the shafts 2. Neighboring rotor bodies are spaced by tubular spacers 26, which can be formed by tubes having a length and wall thickness. A rotor body 3 carried by a shaft 2 projects between rotor bodies 3 carried by a neighboring one of said shafts 2. Between neighboring rotor bodies and between the periphery of rotor bodies on one shaft 2 and the spacers 26 of a neighboring one of the shafts 2, open passages are left through which waste material that is sufficiently small and/or flexible can drop. By replacing the tubular spacers by tubular spacers having a different outer diameter the sorting screen 1 can thus sieve or sort materials of different sizes. Meanwhile, the intermittent motion imparted by the rotating rotor bodies onto the material to be sorted loosens material that is clinging together and brings objects of the material that has not dropped through above next openings in different orientations, so that most objects that can drop through when in a suitable orientation do eventually drop through the sorting screen.

(4) In FIGS. 2A, 2B and 2C an example of a rotor body 3 is shown, having an integrated hub 5 and an outer circumference 10 having a number of radial projections 4 and intermediate recessed portions 6. The hub 5 forms a central body portion extending around a square hole 7 forming a central passage for receiving a shaft 2. The square shape of the hole 7 locks the rotor body 3 against rotation relative to the square shaft 2, so that the rotor body 3 is reliably entrained with rotation of the shaft 2. In operation, the rotor body 3 rotates with the shaft 2 around a central axis of the shaft 2, the rotor body 3 and the square hole 7. Instead of a square hole 7, the central passage may have any other form. However, a form other than circular, such as hexagonal or triangular, is advantageous for providing a form locked fixation about a shaft that is suitably shaped to project outside a largest circular contour within the passage. If the hole is circular a key or room for a key may be provided to reliably entrain the rotor body with rotation of the shaft.

(5) The rotor body 3 according to the present example is provided with eighteen rotor projections 4 projecting radially outwardly from the hub 5 and oriented along a common plane of rotation. Instead of with eighteen rotor projections, the rotor body may be provided with a different number of rotor projections 4. However, to keep variations in the size of the passage along the perimeter of the rotor bodies fairly limited, while providing a high frequency of upward impulses to material on the screen adjacent to each passage, it is preferred that the number of rotor fingers of each rotor body is at least fourteen.

(6) In operation, the sorting screen 1 can for instance sort waste material, such as general household waste, dry co-mingled waste mainly composed of paper, cardboard, glass and plastic waste, or waste paper and cardboard, including flexible, elongated, material, such as fiber, tape, ribbon, rope, cable, wire and/or string material and biological material. The shafts 2 and the rotor bodies 3 mounted thereto are rotated in the first sense of circulation 11 in which upper portions of the rotor bodies move in the direction of transport 18. When waste material is deposited onto an upstream end portion 20 of the sorting screen 1, the rotating shafts 2 convey the waste material in the conveying direction 18. A relatively fine and/or flexible fraction of the material falls through the sorting screen 1 and is collected underneath and a relatively coarse and/or stiff fraction of the material is displaced over the sorting screen 1 and discharged from a downstream end portion 21 of the sorting screen 1.

(7) The rotor body 3 is preferably made of a plastic or elastomeric material, for instance rubber. More in general, it is preferred that the material is quite elastic and preferably has an e-modulus of less than 0.1 GPa and more than 15 MPa, the e-modulus preferably being between 20-30 MPa. For resiliently absorbing impacts and reducing noise emissions, the material is preferably quite soft and preferably has a hardness between 30 Shore A and 90 Shore A, the hardness preferably being between 70 Shore A and 80 Shore A, preferably 73+/5 Shore A.

(8) Each rotor body 3 is provided with a plurality of recesses, in the embodiment shown formed by circular grooves 13, 14, 15, having a different internal diameter and each having a width which matches the wall thickness of a respective end of a tubular spacer 26 to receive and retain the end of a tubular spacer. In different embodiments the grooves can be replaced by a suitable number of projections projecting outwardly from the rotor body for retaining end faces of tubular spacers of different diameters. In case the sorting screen is to be used for sorting waste material of a single size only, the rotor bodies can comprises a single circular groove only to retain a respective tubular spacer and even in this case such a construction provides advantages in particular with regard to maintenance and replacement of defective rotor bodies.

(9) Although in FIG. 1 the outer diameter of the spacers is shown as being identical for all the shafts a sorting screen according to a non-shown embodiment of the invention can contain a number of sections positioned adjacent one another in transport direction 18, in which the outer diameter of the spacers mounted on shafts within one section differs from the outer diameter of the spacers in another section. In this manner within each section material of a different size can be sorted. Preferably, the sections are arranged such that the outer diameter of the spacers reduces from the upstream end portion 20 of the sorting screen 1 to the downstream end portion 21 of the sorting screen 1.