Barrett, William T. (Waukesha, WI)
Potter, Newton I. (Waukesha, WI)

05/318622

05/07/1974

12/26/1972

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Wehr Corporation (Milwaukee, WI)

209/636

209/223.200, 209/930

B03C1/22; B03C1/02; B07C5/344

209/111.8,81A,223R,223A,73

Knowles, Allen N.

Michael, Best & Friedrich

1. A magnetic separator comprising, in combination,

2. The magnetic separator of claim 1 wherein said magnetic assembly also includes a portion located at said curve to generate a magnetic field at said curve and maintain an attractive force on magnetic material traveling

3. The magnetic separator of claim 2 including a plurality of idler rollers

4. The magnetic separator of claim 1 wherein said magnetic assembly varies in magnetic intensity the downstream portions thereof generating a lesser

5. The magnetic separator of claim 1

6. The magnetic separator of claim 1 wherein the portions of said belt upstream and downstream of said curve are both supported for movement along generally straight line paths and both paths are at an angle to the

7. The magnetic separator of claim 1 wherein the portion of said belt

8. The magnetic separator of claim 1 in combination with

9. The magnetic separator of claim 1 in combination with

10. The magnetic separator of claim 8 wherein said magnetic assembly also includes a portion located at said curve to generate a magnetic field at said curve and maintain an attractive force on magnetic material traveling

11. The magnetic separator of claim 8 wherein the portion of said belt

12. The magnetic separator of claim 1 in combination with a supply conveyor for delivering a burden consisting of magnetic and non-magnetic material to said belt upstream of said curve and into the magnetic field generated by said magnetic assembly.

BACKGROUND OF INVENTION

This invention relates to magnetic separators and, more particularly, to magnetic separation of magnetic material in refuse.

With more and more emphasis being placed on recycling, it is becoming more desirable to recover salvageable articles from otherwise discarded material. Much of the metallic material discarded as refuse can generally be recycled for one purpose or another, provided it can be efficiently separated from the remainder of the refuse. The portions intended to be recaptured being metallic are generally also magnetic so that magnetic separation is a possibility for recapture. However, the remainder of the refuse, i.e, other than the metallic articles, although generally not magnetic (e.g., paper), is usually light and tangled with the magnetic portions and thus is carried along with the magnetic material making complete separation difficult if not impossible. Also, in some cases it may be desired to separate the lighter material (e.g., paper) for recycling and again, it is desirable to separate the lighter material from the metallic.

There are various designs of magnetic separators, none of which, to the inventor's knowledge, are well suited to this refuse separator problem because of an inability to insure thorough separation of magnetics from non-magnetics in that environment.

This invention is concerned with this problem and has as one of its objects the provision of effective separation of the magnetic portions of refuse from the non-magnetic portions thereof.

SUMMARY OF INVENTION

For the achievement of that and other objects, this invention proposes a magnetic separator having a continuous belt moving past a magnetic assembly which generates a magnetic field through which the belt moves. The belt is supported such that it has a curve in the lower portion of its path of movement and a straight line portion upstream of the curve. The magnetic assembly is located and generates a magnetic field in the area of the straight line portion and the curve. The magnetic assembly, and the field generated thereby, extend on both the upstream and downstream sides of the curve, i.e., relative to the direction of travel of the belt. On the upstream side of the curve the belt follows a straight line path and, if desired, the belt may also follow a straight line path on the downstream side of the curve. Material being attracted to the belt by the magnetic assembly and thus traveling along with the belt, must negotiate the curve and at the curve there will be some displacement, i.e., agitation, of the material traveling with the belt. This agitation tends to dislodge any non-magnetics being carried along with the magnetics.

In a preferred embodiment the magnetic assembly also includes a magnetic portion at the curve to insure a magnetic field in that area strong enough to prevent the magnetics from falling completely away from the belt. Also, agitation is further enhanced by the magnetic assembly presenting alternating polarities to the belt and thus to the material attracted thereto.

Preferably the belt on both the upstream and downstream sides of the curve is disposed at an angle to the horizontal thereby taking better advantage of gravity, with the agitation, to achieve complete separation.

The supply conveyor which delivers the refuse to the separator runs at an angle to the upstream portion of the magnetic field and the portion of the belt in that area. It is advantageous to mount the magnetic separator for movement toward and away from the end of the supply conveyor to accommodate different burden depths on the conveyor.

To counteract wear of the belt, the belt can be driven from the head pulley so that the back or non-working side of the continous belt loop is under tension and the lower or working side can be relatively slack. In addition, or as an alternative, rollers can be provided at the curve to support the belt.

DESCRIPTION OF DRAWINGS

FIG. 1 is a side view of a combination refuse separator and supply conveyor partially in section;

FIG. 2 is an end view of the refuse separator of FIG. 1; and

FIG. 3 is a side view similar to FIG. 1 but illustrating an alternative construction and arrangement of the refuse separator.

DESCRIPTION OF PREFERRED EMBODIMENT

With particular reference to the drawings; a refuse separator 10 is illustrated in combination with a supply conveyor 12, receptacle 14 and a splitter baffle 16. The function of the receptacle and splitter baffle is to physically segregate separated magnetic and non-magnetic material, therefore no particular form of either is necessary and in fact only one of the two could be used if desired.

The refuse separator is intended to receive burden 18 from supply conveyor 12 and carry the magnetic portion of the burden over splitter baffle 16 while the non-magnetic material falls, by reason of gravity, into receptacle 14. To this end, the separator includes belt 20 which travels in a counterclockwise manner around idler rollers 22 and 24 and head and end pulleys 26 and 28. Head pulley 26 is connected to drive motor 30 through a belt drive 32 and a gear box so that the head pulley becomes the drive member through which the driving force is imparted to belt 20. In this manner, the belt travels in a continuous, closed path under the influence of drive pulley 26. As viewed in FIG. 1, the closed path has an upper portion (between end pulley 28 and idler 22) and a lower portion (between head pulley 26 and end pulley 28).

Magnetic assembly 36 is located within the area defined by belt 20. The magnetic assembly consists of a lead magnet 38 having a central core 40 surrounded by an electrical coil 42 and housed within a U-shaped in cross section housing 44 with core 40 engaging the backplate 46 of the housing. This is a conventional electromagnet construction and when coil 42 is energized the end of core 40 adjacent belt 20 will assume one magnetic polarity, e.g. north, and the outer ends of sides 48 and 50 of the housing will assume an opposite magnetic polarity, south. Plate 52 is a pole piece provided to concentrate the emanation of flux at the belt.

Downstream of the lead magnet assembly is a trailing magnetic assembly consisting of a backplate 54 and four magnetic assemblies, 56, 58, 60, and 62 projecting from the backplate 54 toward the belt. Each of the magnetic assemblies can be made of permanent magnetic material such as barium titanate waffers, which are magnetized through their thickness dimension, i.e., at right angles to backplate 54, and stacked with the thickness dimension of each magnetic waffer in an assembly 56, 58, 60, or 62 extending in a common direction. By controlling the orientation of the magnetic waffers the magnetic polarity presented by each of the magnetic assemblies to the belt can be controlled so that, for example, a north magnetic polarity is presented by each of assemblies 56 and 60 and a south magnetic polarity is presented by each of assemblies 58 and 62. It will be noted that the alternating polarity started at the lead magnetic assembly is maintained through the trailing magnetic assembly.

It will be appreciated further that the entire magnetic assembly could be made of electromagnets or permanent magnets as desired or as illustrated in it can be a combination of permanent and electro. To complete the magnet assembly a plate, either in one piece or a weldment, 64 extends between the magnetic assembly and the inside surface of belt 20.

The idler rollers and pulleys and head pulley 26 together with the magnetic assembly are all supported from a common frame structure, a portion of which, 66 and 68, is illustrated in FIG. 2. Since a showing of the complete structural framework of the refuse separator is not necessary to an understanding of this invention, this general description of the support structure is believed to be adequate.

With reference to FIG. 1, magnet assembly 36 generates a magnetic field at belt 20 and at the lower portion of the path through which the belt travels. Conveyor 12 is arranged so that it discharges burden 18 into this magnetic field and the magnetic material contained in the burden is attracted to the belt 20 in the area of lead magnet 38. The non-magnetic material such as paper, will fall by gravity into receptacle 14 and the magnetic material travels with belt 20 beyond splitter 16 where the magnetic field terminates. The magnetics are discharged on the side of the splitter baffle opposite to the receptacle. Also, to take advantage of the fact that once the magnetics are attracted to the belt less magnetic force is required to hold them on the belt than to attract them initially, the magnets can be made to diminish in strength from lead magnet 38 through the trailing magnets. That is, magnetic assemblies 56, 58, 60, and 62 can be made progressively weaker from the curve toward end pulley 28.

Paper and like non-magnetic material, being relatively light, is extremely prone to being tangled with the magnetic material and carried along with it into engagement with and on belt 20 such that it cannot fall into receptacle 14. To provide means for dislodging this entrapped non-magnetic material, this invention intends to provide agitation of the burden carried by belt 20 without losing the magnetic material. To this end, a curve 70 is provided in the lower portion of the path of belt 20 in the area of the magnetic assembly. With respect to the direction of travel of belt 20 and, still in the lower portion of the path, the belt follows straight line paths on both the upstream and downstream sides of the curve and all lead magnet 38 is located upstream of curve 70 and the trailing magnet portion of the magnetic assembly is located downstream of the curve. Because of the curve 70, the material adhered to the belt must change direction at the curve and since the non-magnetic material does not have the magnetic attractive force to hold it on the belt, it tends, due to centrifugal force, to proceed in a straight line trajectory rather than make the curve. Also it has been observed that, again due to centrifugal force, some physical separation of the magnetic material from the belt occurs at the curve, but not completely from the magnetic field so that the magnetic material returns to the belt after the curve has been negotiated, and this causes agitation at the curve which further tends to dislodge the non-magnetic material.

Also, the preferred embodiment illustrated in FIG. 1 shows the upstream and downstream portions of the belt adjacent curve 70 both positioned at an angle to a horizontal plane, this arrangement makes maximum use of the force of gravity in separating the non-magnetics. That is, the turn at the curve utilizes basic inertia and gravity to achieve some separation and the belt proceeding generally upward from the curve increases the pull of gravity on the non-magnetic materials to enhance separation.

For effective introduction of the burden from supply conveyor 12 to the magnetic separator, conveyor 12 is arranged at an angle to the magnetic separator. Conveyor 12 is arranged at an angle for the horizontal so that the burden comes into the belt in the area of lead magnet 38 at an angle. This brings the material into the belt generally in the direction of the flux lines making up the magnetic field for most effective separation.

In order to accommodate different depths of burden, the entire refuse separator is supported for horizontal movement toward and away from the conveyor 12. More specifically, and with reference to FIG. 2, a pair of support brackets 72 and 74 extend from frame member 66 and 68 on opposite sides of the refuse separator. Two pairs of these support brackets are provided. One at the head end and one at the opposite end of the magnetic separator but only one is illustrated in the drawings. The support brackets have an elongated channel member 76 and 78 attached to their undersides and each supports a roller 80 and 82. The rollers engage I-beam rails 84 and 86 which are mounted on frames 88 and 90. The refuse separator can then be moved horizontally toward and away from the discharge end of the supply conveyor, this can be accomplished either manually or through some suitable mechanical arrangement.

A plurality of conventional lugs 92 are provided on the working face of belt 20 to assist in carrying the material along with the belt.

At this point, it should also be noted that certain advantages attach to utilizing the head pulley 26 as the drive pulley. By doing this, it is the backside 94 of the belt which is maintained under tension and the working side of the belt, i.e., that passing through the magnetic field, can be supported to hang relatively slack. This has a tendency to minimize belt wear.

Also, the alternating magnetic polarities along the path of travel of the belt provide agitation of the magnetic material attracted to the belt to further enhance separation. That is, the magnetics being forced to pass through alternately different magnetic fields will, in effect, roll around and not hold a stationary position on the belt.

FIG. 3 illustrates an alternative construction of the refuse separator and arrangement with respect to supply conveyor 12, receptacle 14 and splitter baffle 16. In this embodiment, the upstream portion 96 of belt 20 is arranged at a sharper angle to the horizontal than in FIG. 1 and the downstream portion 98 is in a horizontal plane. Magnetic assembly 102 again includes lead magnet 104 which generates a magnetic field at the end of conveyor 12 and in the area of the upstream portion 96 of the belt and a trailing portion 106 which is positioned downstream of the curve and generates a magnetic field in that area. These magnetic assemblies can be constructed the same as illustrated in connection with FIG. 1 again maintaining the alternating magnetic polarities.

In the FIG. 3 embodiment a third magnetic assembly 108 is provided at curve 100 to insure an adequate magnetic field at the curve to prevent loss of the magnetics. The additional magnetic assembly 108 maintains the alternating polarities discussed previously.

In the FIG. 3 embodiment the drive for belt 20 is provided through end pulley 110. With this arrangement, the working portion of the belt will now be under tension and to miminize wear at curve 100 a plurality of stainless steel rollers 112 are provided in that area as support for the belt.

Again, the refuse separator of FIG. 3 can be positioned for horizontal movement relative to the end of conveyor 12 and it will again be noted that the burden is discharged into the face of belt portion 96 so that it is generally in line with the magnetic lines of flux making up the magnetic field.

As in FIG. 1, magnetics will be attracted to the lower portion of the path of travel of belt 20 as the burden is discharged from supply conveyor 12. The non-magnetics fall into receptacle 14, and the magnetic material is agitated as it travels along with the belt through the magnetic field to further dislodge non-magnetics before splitter 16 is reached at which point the magnetics fall from the belt behind the splitter baffle.

Although this invention has been illustrated and described in connection with particular embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications may be made therein without departing from the spirit of the invention or from the scope of the appended claims.