This invention pertains to screens for comminuting machines. More particularly, this invention pertains to one or more sizing screen arrangements for use with a rotary grinder.
Various machines have been developed for comminuting materials. Examples, with common names, include: shredders, having a relatively slow speed comminuting apparatus typically used for ripping and breaking hard, tough materials apart into relative coarse particles; chippers having a relatively high speed comminuting apparatus (either a rotating disc or a rotating drum) with sharp material reducing components typically used for cutting wood materials into small chips; and grinders having a relatively high speed comminuting apparatus (e.g., a rotating drum typically with robust and blunt material reducing components) that is located adjacent a sizing screen that is used to tear and shatter materials into a variety of particle sizes.
Grinders typically include reducing hammers on which replaceable grinding cutters (i.e., grinding tips or grinding elements) are mounted. Grinding cutters generally have relatively blunt ends suitable for reducing material through blunt force impactions. Screens are often used to control the size of the reduced material output from grinders. In contrast to the grinding cutters used on grinders, chippers typically include relatively sharp chipping knives configured to reduce material through a cutting/slicing action as opposed to a grinding action.
Aspects of the disclosure relate to a grinder for grinding relatively loose materials. The grinder includes a reducing unit including a plurality of cutters disposed on hammer members; and an arcuate screen positioned concentric to the reducing unit. The arcuate screen defines multiple tracks of apertures. Each track of apertures extends in the path of travel of one of the cutters so that only one respective cutter passes over each track and each cutter passes over only the respective one of the tracks. A width of each cutter is wider than a width of the respective track.
Other aspects of the disclosure relate to a screen for use with a grinder including an arcuate body having a screening defining plurality of apertures. The apertures are arranged in tracks that extend parallel to an upstream-to-downstream dimension of the screening region. Each aperture defines a parallelogram having one pair of edges extending parallel to the upstream-to-downstream dimension of the screening region. Each aperture also has a second pair of edges that are angled relative to the upstream-to-downstream dimension of the screening region. Each aperture defines a downstream corner that is located farther downstream along the upstream-to-downstream dimension than any other portion of the aperture. The downstream corner has a radius of at least 3/16 of an inch.
Other aspects of the disclosure relate to a screen arrangement for use with a grinder including a first screen having an arcuate body. The arcuate body has a screening region defining plurality of apertures; and a fastening region that extends between the screening region and a perimeter of the arcuate body. The fastening region defines notches that are differently shaped than the apertures of the screening region.
Other aspects of the disclosure relate to a screen arrangement including a frame including a plurality of parallel support arrangements coupled together by a plurality of parallel cross-piece arrangements; a plurality of arcuate screens configured to be coupled to the frame; and a plurality of coupling members configured to secure the screens to the frame. Each screen includes a fastening region at which notches are disposed. A fastening section of each coupling member is configured to fit within one of the notches of at least one of the screens and is configured to be fastened to one of the support arrangements of the frame. A clamping section of each coupling member is configured to extend over an inner surface of the at least one of the screens.
A variety of additional aspects will be set forth in the description that follows. These aspects can relate to individual features and to combinations of features. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the broad concepts upon which the embodiments disclosed herein are based.
Reference will now be made in detail to the exemplary aspects of the present disclosure that are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like structure.
Comminuting machines each have an infeed section, a comminution section, and a discharge section. The comminution sections include rotary reducing units used to reduce material through comminution actions such as grinding, cutting, chopping, slicing, chipping, etc. The rotary reducing units can include carriers (e.g., drums or other carriers) that carry a plurality of reducing components (e.g., edges, grinding members, cutters, plates, blocks, blades, bits, teeth, hammers, shredders or combinations thereof) around rotational cutting paths surrounding central axes of rotation of the carriers. Example carriers are disclosed in U.S. Pat. Nos. 7,204,442; 5,507,441; 7,213,779; and 6,840,471, the disclosures of which are hereby incorporated herein by reference
In use, the carriers are rotated about their axes to cause the reducing components to impact material desired to be reduced, thereby causing reduction of the material via one or more comminution actions. One or more screens can be provided at least partially surrounding the rotary reducing units for providing additional comminution action and/or for controlling the size of the reduced material output from the comminution machines. Example comminution machines in accordance with the principles of the present disclosure can include tub grinders, horizontal grinders, chippers, shredders or other material reduction machines.
Referring to
In some implementations, the hammer members 110 are generally orthogonal to the rotation axis X. In other implementations, however, the hammer members 110 may be oriented at an angle ranging between 50° and 130° from the rotation axis X (e.g., see
Cutters 120 are mounted (e.g., using fasteners) to distal ends of the hammer members 110. In the example shown, a block-style cutter 120 is mounted to a leading face at each of the opposite ends of each hammer member 110. In other implementations, the cutters 120 may be mounted directly to a drum or other type of rotational carrier. In still other implementations, blade-style cutters may be mounted to the hammer members 110 instead of or in addition to the block-style cutters 120. As the hammer members 110 are rotated about the axis X, each of the cutters 120 spins along a respective annular cutting path. The cutters 120 engage and crush waste material that enters the cutting paths.
In some implementations, each hammer member 110 extends from a first distal end to a second distal end. A first cutter 120A (
A front side 122 of each cutter 120 can be referred to the “reducing side” or “leading side” of the cutter 120. During the reduction of material, the cutter 120 is moved such that the front side 122 leads the cutter 120 and impacts the material desired to be reduced. The front side 122 of the cutter 120 includes a main central region (i.e., a main central face) defining openings that are configured to receive fasteners to secure the cutters 120 to the hammer members 110.
The front side 122 also includes reducing edges 124, 126 positioned on opposite sides of the main central region. The reducing edges 124, 126 extend across a width of the block-style cutter 120. The reducing edges 124, 126 are parallel to one another. In some implementations, the first and second reducing edges 124, 126 are wedge-shaped and project forwardly from the main central region of the block-style cutter 120. These edges 124, 126 can have a rounded/blunt configuration adapted for grinding material desired to be reduced. In other embodiments, the edges 124, 126 can be sharp edges, such as knife edges, adapted for chipping material being reduced.
As shown at
A sizing screen arrangement 130 is mounted to the reducing unit 100 so as to extend at least partially around the reducing unit 100. The sizing screen arrangement 130 is mounted at a position offset from the reducing boundary RP of the reducing unit 100 so that the cutters 120 may freely spin within the volume of the screen arrangement 130. In certain implementations, the sizing screen 130 is offset from the reducing boundary RP by a distance ranging between 0.4 and 0.2 inches. When the waste material intersects the reducing perimeter RP, the material is impacted by the cutters 120 and initially reduced. Contact between the material and the cutters 120 forces the material into a comminution chamber 131 (
The comminution chamber 131 is defined between the reducing unit 100 and the sizing screen 130. Within the comminution chamber 131, the material is ground and sliced by the cutters 120. The sizing screen arrangement 130 defines one or more exit apertures 145 through which material falls from the chamber 131 during operation of the reducing unit 100. Waste material drops through apertures 145 of the sizing screen 130 to a discharge system that carries the reduced material away from the comminution chamber 131 to a collection location. In certain implementations, the discharge system includes a conveyer belt and/or a conveyor for discharge from the reducing machine (e.g., from the tub grinder or horizontal grinder).
Each sizing screen arrangement 130 includes at least one screen 132 mounted to a frame 150.
The screening region 140 of the example screen 132 has an upstream-most boundary 141 separated from a downstream-most boundary 142 by an upstream-to-downstream screen dimension D (
The apertures 145 of the screening region 140 are arranged in rows R that extend along the upstream-to-downstream dimension D of the screening region 140. Each row R defines a plurality of apertures 145. In certain implementations, each row R includes a plurality of pairs 146 of laterally aligned apertures 145. Each row R is located on the screening region 140 such that only one of the hammer members 110 of the reducing unit 100 is aligned with that row R. The rows R also are located so that each hammer member 110 is aligned with only the respective one of the rows R.
In some implementations, the apertures 145 in each row R are aligned along one or more tracks T that extend parallel to the upstream-to-downstream dimension D. In certain implementations, each row R includes a first track Ti and a second track T2. In some such implementations, the aperture pairs 146 are disposed so that a first aperture 145 of each pair 146 is located in the first track T1 and a second aperture 145 of each pair 146 is located in the second track T2. In certain implementations, the first cutting path of the first cutter 120A of each hammer member 110 aligns with the first track T1 of the respective row R and the second cutting path of the second cutter 120B of each hammer member 110 aligns with the second track T2 of each row R.
In some implementations, the screen 132 has an even number of tracks T1, T2. In other implementations, however, the screen 132 has an odd number of tracks T1, T2. In such implementations, one track of the screen 132 cooperates with a track of an adjacent screen 132 in the screen arrangement 130 to form a row R. In certain implementations, a screen 132 having an even number of tracks may have two tracks that form rows with adjacent screens (e.g., one track at the left side and one track at the right side). In the example shown in
In some implementations, the cutters 120 are not arranged relative to the screen 132 so that the first reducing edges 124 are parallel to the inner surface of the screening region 140. Rather, the cutters 120 may be oriented (e.g., tilted) so that one side or corner 125 of the first reducing edge 124 is disposed closer to the inner surface of the screening region 140 than the opposite side or corner 127 of the first reducing edge 124 (e.g., see
In the example shown in
In some implementations, the second pair of edges 148 of the apertures 145 of the first track Ti of one or more rows R are angled in a first direction relative to the dimension D and the second pair of edges 148 of the apertures 145 of the second track T1 are angled in a second direction that is different from the first direction. In certain implementations, the apertures 145 of each track T1, T2 of one or more rows R are angled towards each other, thereby forming a chevron-style pattern or portion thereof.
Each aperture 145 defines a downstream corner 149 that is located farther downstream along the flow direction F than any other portion of the aperture 145. In certain implementations, the cutters 120 are positioned so that the side 125 of the reducing edge 124 of the respective cutter 120 that is closest to the screen 132 passes over the downstream corner 149. In certain implementations, the downstream corners 149 of aperture pairs 146 face each other (see
The fastening region 137 defines one or more notches through which a coupler member (e.g., coupler member 160) may extend to secure the screen 132 to the frame 150. In some implementations, the notches are shaped differently than the apertures 145 defined in the screening region 140. For example, the notches may have a different size, pattern, or orientation from the apertures 145. In the example shown, the notches define a generally rectangular shape that is elongated along the upstream-to-downstream dimension D of the screen 132. In other implementations, the notches may have a different shape. In certain implementations, the notches extend over a greater distance along the upstream-to-downstream dimension D than any of the apertures 145. In other implementations, the notches may be smaller than the apertures 145.
In some implementations, one or more of the notches are open-ended notches 138 (e.g., see
One or more coupling members 160 are configured to hold the screen 132 to the frame 150. One example coupling member 160 is shown in
The clamping section 164 of each coupling member 160 is configured to extend over a portion of the fastening section 137 of at least one screen 132. In the example shown, the clamping section 164 extends over the inner surface of the screen 132. In some implementations, the clamping section 164 overhangs at least one side of the fastening section 162. In certain implementations, the clamping section 164 overhangs opposite sides of the fastening section 162. In the example shown, the clamping section 164 is elongated along a longitudinal axis of the coupling member 160 and overhangs the clamping section 164 along the longitudinal axis. In other implementations, however, the clamping section 164 may overhang lateral sides of the fastening section 162 instead of or in addition to the longitudinal sides.
For example,
The screen 132, coupling members 160, and fasteners 168 are shown exploded outward from the support arrangement 152 in
For example,
The aperture tracks T1, T2 of longitudinally adjacent screens 132 align to form extended tracks along the flow direction F. In the example shown, the tracks T1, T2 are paired into eight rows R1-R8 that are laterally spaced along the screen arrangement 130. The top left screen 132A includes two complete rows R1 and R2. The top left screen 132A also includes the first track T1 of the third row R3. The top middle screen 132B includes two complete rows R4 and R5. The top middle screen 132B also includes the second track T2 of the third row R2 and the first track Ti of the sixth row R6. In other implementations, however, each screen 132A-132F may include only complete rows of apertures 145.
In the example shown in
In the example shown, the tracks of apertures 145 are paired into ten rows R1-R10 that are laterally spaced along the cross-dimensions CD of the screens 132. The left and right screens 132G, 132I each include three complete rows R1-R3, R8-R10, respectively. Each of the left and right screens 132G, 132I also includes one of the tracks of one row R4, R7. The middle screen 132H includes two complete rows R5 and R6. The middle screen 132H also includes the other track of the two of the rows R4, R7. In other implementations, however, each screen 132 may include only complete rows of apertures 145.
In the example shown in
The above specification, examples and data provide a complete description of the manufacture and use of the composition of the invention. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.
The present application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/593,613, filed Feb. 1, 2012, which application is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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61593613 | Feb 2012 | US |