DESCRIPTION AN IMPROVED APPARATUS FOR COMMINUTING SOLID WASTE MATERIALS Technical Field This invention relates to apparatus for comminuting solid waste material such as plastic sheet material. Background Art
During the manufacture and forming of many products from plastic, significant amounts of plastic waste material is frequently produced. Applicant has previously invented a unique apparatus for comminuting waste material, particularly plastic sheet material, into small, rather uniform particles or pieces that can be readily recycled or disposed of in an environmentally acceptable manner. Such prior invention is the subject of the Irwin et al. U.S. Patent No. 4,687,144, granted August 18, 1987 and assigned to Irwin Research & Development, Inc.
Such prior invention was a vast improvement over various types of hammermills that had previously been used. The hammermills were quite bulky, extremely noisy, and prone to substantial damage when the mill received foreign material that it could not comminute. Although such prior Irwin et al. invention was a vast improvement and was commercially successful, particularly in view of hammermill, it was rather expensive to manufacture and sometimes noisy in operation when processing certain material. Furthermore, it was unable to satisfactory comminute rather high density plastic materials.
The objective of the present invention is to provide a vastly improved comminuting apparatus that is not only able to process significantly greater amounts of material in a given time, but is also less expensive to manufacture and quieter in operation. Furthermore the present invention provides an apparatus that is able to comminute a wider variety of solid waste products. Brief Description of the Drawings Preferred embodiments of the invention are described below with reference to the accompanying drawings, which are briefly described below.
Fig. 1 is a plan view of a preferred embodiment of the apparatus illustrating the top exterior of the apparatus with a waste material entrance; Fig. 2 is a front view of the apparatus illustrated in Fig. 1. Fig. 3 is a transverse vertical cross-sectional view taken along line 3-3 in
Fig. 2 illustrating the interior of the apparatus;
Fig. 4 is a longitudinal vertical cross-sectional view taken along line 4-4 in Fig. 1 illustrating the interior of the apparatus;
Fig. 5 is a series of illustration views of the waste material and the reduction of the waste material into smaller and smaller particles of the material is progressively processed and reduced to a desired particulate size;
Fig. 6 is a product flow illustrative diagram showing the flow path of the waste material through the apparatus as the material is being progressively process and reduced to the desired particulate size;
Fig. 7 is an isolated vertical cross-sectional view of a set of scissor roll rings illustrating the initial entrance of a piece of waste material between the scissor rolls;
Fig. 8 is an isolated vertical cross-sectional view similar to Fig. 7 except showing the scissor roll rings incrementally rotated to sever the piece of waste material; Fig. 9 is a vertical cross-sectional view taken along line 9-9 in Fig. 2;
Fig. 10 is horizontal cross-sectional view taken along line 10-10 in Fig. 9; and
Fig. 11 is fragmentary top view with a portion of a top wall removed to illustrate scissor rolls emphasizing the location and spacing of scissor roll ring finger knives.
Best Modes for Carrying Out the Invention and Disclosure of Invention
A preferred embodiment of this invention is illustrated in the accompanying drawings, illustrating a waste comminuting apparatus generally designated with the numeral 10 in Figs. 1, 2 and 4 for receiving solid waste material 12 and for reducing the solid waste material progressively into smaller and smaller sizes until a desired small particulate or piece size is obtained as illustrated in Fig. 5.
It should be noted that the apparatus 10 is very compact even through the material is progressively reduced in size in several stages to a desired predetermined small size. The predetermined small piece size will generally depend upon the desires of the customer, the end use, and the particular material being comminuted. The solid waste material 12, illustrated in Fig. 5, is progressively reduced to subdivided pieces 14a through 14e. When the subdivided pieces are finally reduced to the desired small size 14e, they are removed from the apparatus as the final product. Those subdivided pieces that
have not been sufficiently reduced to the desired small size are reprocessed or recycled until they are sufficiently reduced to the desired size.
The apparatus 10 has a general frame 16 that may be self-supported or affixed to other apparatus such as the discharge of a thermo-forming machine for receiving the solid waste material 12 directly from a thermo-forming machine and reducing the material for reuse. The frame 16 generally includes a general enclosure 18 that includes a front wall 20, side walls 22, 24, back wall 26, a bottom wall 28 and a top wall 30. The top wall 30 has a material entrance 32 (Figs. 1 and 3) through which the solid waste material is fed into the apparatus 10. The general frame 16 may be supported on legs 17a that have wheels 17b. The general frame 16 preferably includes upper cross-frame members 34 and 36 and lower frame members 38 and 40 that are illustrated in Fig. 3.
Within the enclosure 18, two scissor rolls 42 and 44 are mounted in an intermeshing relationship for rotation in opposite directions in coordination with each other to receive the solid waste material 12 and to shear the solid waste material as the material passes between the scissors rolls 42 and 44. The scissors rolls 42 and 44 are positioned within the enclosure 18 between an intake manifold 46 that receives the material through the entrance 32. The material, after passing through the scissor rolls descends into an outtake manifold 48 (Fig. 3).
The scissor roll 42 is mounted on a shaft 50 that rotates about axis 52. The scissor roll 44 is mounted on a shaft 54 that rotates about axis 56. Axes 52 and 56 are parallel with each other and extend between the side walls 22 and 24. The axes 52, 56 are positioned so that the scissor rolls 42, 44 have sufficient overlap to shear the material between the scissor rolls as the material passes between the rolls. The shafts 50 and 54 are supported for rotation by respective bearings 57 (Fig. 4). Each of the shafts 50 and 54 have hexagonal cross-sectional profiles, providing angular drive surfaces 58. Each of the scissor rolls 42 and 44 include a plurality of scissor rings 60 in which each of the rings 60 has an outer circular peripheral surface 62 and an inner hexagonal bearing surface 64 that is complementary to the profile of the shafts 50 and 54 so that the scissor rings 60 rotate in response to the rotation of the shafts 50 and 54. Each of the scissor rings 60 include side surfaces that form shearing edges 68 with the outer peripheral surface 62 (Fig. 11).
In the preferred embodiment, each of the scissor rings 60 have evenly angularly spaced finger knives 70 formed integrally on the scissor rings 60 and projecting radially outward of the surface 62 and forward in the direction of rotation for gripping, puncturing and transversely cutting the solid waste material 12 as illustrated in Figs 7 and 8. Each of the finger knives 70 include a projecting body 71 that projects radially outward from the peripheral surface 62 and projects forward in the direction of rotation. Each of the finger knives 70 includes side shearing surfaces 72 and an undercut surface 74 forming a sharp knife point 76. The scissor ring finger knives 70 are intended to grip, puncture and transversely cut each piece as it is being sheared between the rings 60.
Each of the scissor rolls 42 and 44 further include a plurality of ring spacers 80. Each spacer 80 has a circular outer peripheral surface 82 and an inner hexagonal surface 84 (Figs. 7 and 8). Each of the ring spacers 80 have a width that is slightly greater than the width of the spacer rings 60. Each of the spacer rings 60 and ring spacers 80 are alternately positioned on the shafts 50 and 54 so that a scissor ring 60 on one scissor roll opposes a corresponding ring spacer 80 on the other scissor roll creating a circular inter-roll cavity 86 (Fig. 11) between the adjacent rings and outward of the intermediate ring spacers 80. Once the material 12 is cut and sheared, it is received in the inter-roll cavity 86 and passes between the rolls 42 and 44 into the outtake manifold 48.
The axes 52 and 56 of the rolls are sufficiently spaced so that there is a slight overlap of approximately Vβ inch in the profile of the scissor rings so that as they are rotated, the material is sheared by the shearing edges 68 and the knife fingers 70 as the profile of the scissor rings 60 move into the circular inter-roll cavity 86 of the opposing ring spacer 80.
The intake manifold 46 has an entrance intake manifold section 90 and a recycle intake manifold section 92 illustrated in Figs. 3 and 6. The sections 90 and 92 are separated by a divider 94. New solid waste material 12 enters through the entrance 32 into the entrance intake manifold section 90 and subdivided material requiring additional recycling is circulated back into the intake manifold section 92.
The outtake manifold 48 includes an outlet 96 (Figs. 4 and 6) and an airstream recirculation inlet 98 to facilitate the removal of the severed pieces from the outtake manifold 48 and to entrain such pieces 14 in an airstream.
The apparatus includes a scissor roll drive generally designated with the numeral 100 illustrated in Figs. 1, 2 and 4 having a motor 102 connected to a speed reduction gear box 104. The box 104 is operatively connected to the shafts 50 and 54 for rotating the shafts counter to each other in the directions illustrated in Figs. 3, 7 and 8.
The apparatus 10 further includes a pneumatic conveyor generally designated with the numeral 110 for conveying the subdivided pieces 14 from the outtake manifold 48 and directing the pieces to a separator screen 131 to impinge the subdivided pieces against the screen 131 to direct small subdivided pieces 14e through the screen and to carry large subdivided pieces 14a-14d away from the screen 131 and return the large pieces 14a-14d back to the shear intake manifold 46 to further reduce the size of the large subdivided pieces.
The pneumatic conveyor 110 includes a centrifugal fan 112 for generating an airstream of sufficient velocity and volume to remove the subdivided pieces from the shear outtake manifold 48 and to entrain the pieces 14a-14e in the airstream. The centrifugal fan 112, illustrated in Figs. 9 and 10, includes a housing 114 having a central propeller section 116 and a peripheral volute section 118. The central propeller section 116 includes a central inlet 120 with a propeller assembly 122 mounted within the central propeller section 116. The propeller assembly 122 includes a shaft 124 with radial blades 126 extending radially outward for directing the air from the central inlet 120 radially outward and tangential into the peripheral volute section 118. A motor 128 is connected to the shaft 124 for rotating the blades 126 at the desired speed to obtain an airstream having the desired velocity and volume. The separator screen 131 is mounted within the centrifugal fan housing 114 as illustrated in Figs. 6, 9 and 10. The separator screen 131 is formed in an arcuate shape, and is mounted in the peripheral volute section 118 subdividing the section 118 into an inner volute chamber 133 and an outer volute chamber 135. The path of the airstream in the inner volute chamber 133 is illustrated by the path arrow 134. The path of the airstream in the outer volute chamber 135 is illustrated by the path arrow 136.
The centrifugal fan 112 has an outer volute duct 137 with a product outlet 139 for discharging the small particles 14e that have passed through the separator screen 131 from the centrifugal fan 112. Additionally, the centrifugal fan 112 has a recycle outlet 143 associated with the inner volute 133 for discharging the larger subdivided pieces 14a-14d that do not pass through the
screen 131. The inner volute chamber 133 has an inner volute duct 141 that is substantially tangent to the path of the blades 126 for directing a portion of the airstream from the fan through the recycle outlet 143. As previously mentioned, the blades 125 when rotated direct the air and the entrained subdivided pieces radially outward from the central inlet 120 to impinge against the screen 131 in a radial and tangential direction with the small pieces 14e passing through the screen 131 and the large pieces 14a-14d being deflected from the screen and carried by a portion of the airstream from the fan out through the inner volute duct 141. The inner volute duct 141 includes a recycle outlet 143 for discharging- a portion of the airstream containing the entrained large pieces that do not pass through the separator screen 131.
A recirculation outlet 145 is formed in the inner volute duct 141, but angularly spaced from the recycle outlet 143 a sufficient distance so that a additional airstream discharge path is created containing a minimum of the large pieces 14a-14d. The recycle outlet 143 taps a portion of the airstream from the duct 141 at a sharp angle to the normal flow of the airstream and entrained large pieces so that the momentum of the entrained large pieces continue in their normal direction out the recycle outlet 143. The pneumatic conveyor 110, besides the fan 112, further includes a removal conduit 148 extending between the outlet 96 of the outtake manifold 48 and the central inlet 120 of the centrifugal fan 112 as illustrated in Figs. 4 and 6. The pneumatic conveyor 110 includes a recycle conduit 150 that extends between the recycle outlet 143 of the fan housing 114 and the recycle intake manifold section 92 (Figs. 1, 2 and 6). A recirculation conduit 152 extends between the recirculation outlet 145 of the fan housing 114 and the airstream recirculation inlet 98 of the outtake manifold 48 illustrated in Figs. 4 and 6.
As illustrated in Figs. 3 and 6, the cross-frame members 38 and 40 have notched stripping fingers 158 formed on an edge thereof projecting between the scissor rings 60 and into the inter-roll cavities 86 along the lower profile of the scissor rolls 42 and 44 to strip any of the subdivided pieces from between the scissor rings 60 after the pieces have been severed.
During the operation of the apparatus 10, solid waste material 12 is fed into the apparatus 10 through the material entrance 32 and into the intake manifold 46 where it is directed to the scissor rolls 42 and 44. As the material engages the rolls, it is gripped by the finger knives 70 and pulled between the
scissor rolls 42 and 44 with the scissor rings 60 and its shearing edges 68 shearing the solid waste material into subdivided pieces. As previously mentioned, the finger knives 70 grip the material, puncture the material and transversely cut the material as it passes between the rolls. The severed pieces 14a-14e then descend into the output manifold 48. The stripper fingers 158 strip any severed pieces from the rolls 42, 44 and into the outtake manifold 48.
The airstream created by the centrifugal fan 112 is directed through the outtake manifold 48 from the inlet 98 and the outlet 96 to entrain the subdivided pieces 14a-14e into the airstream which is directed by the removal conduit 148 to the propeller assembly 122 of the centrifugal fan 112. The blades 126 direct the airstream and the entrained subdivided pieces 14a-14e radially and tangentially outward against the arcuate separator screen 131 to cause those pieces 14e that are less than a predetermined size to pass through the screen into the outer volute chamber 136. Those subdivided pieces that are larger than the apertures or holes in the separator screen 131 are carried along the inside of the screen in the inner volute chamber 133 and out the inner volute duct 141 (Fig. 6). The recycle conduit 150 directs the airstream with the entrained large subdivided pieces into the recycle intake manifold section 92 for reprocessing and reduction through another pass of the scissor rolls 42 and 44. A portion of the airflow is syphoned off through the recirculation outlet 145 and is recirculated back through the recirculation inlet 98 into the output manifold 48. The small pieces 14e that pass through the separator screen 131 are directed from the apparatus through the product outlet 139. The large particles or pieces 14a-14d will be continually recycled until their size is reduced below that of the preselected size of the apertures of the separator screen 131.
It should be noted that the apparatus 10 is designed to operate at a very low speed with .the scissor rolls 42 and 44 rotating at less than 60 rpm. Should any foreign material enter into the apparatus, it will not damage the equipment as the scissor rolls can, if jammed, stop the motor 102 without damaging the rolls particularly the shearing edges 68.
It should be also noted that the machine operates very quietly, even though substantial shearing action is taking place. For many applications, the apparatus is sufficiently quiet, which does not require operator's to wear noise reduction ear-protecting devices when standing nearby.