Firing ranges or gun ranges are training or practice areas where firearms are fired at targets. When a weapon is fired, a projectile is propelled out of the weapon and lands down range near the target. Outdoor ranges are typically built with a dirt berm positioned behind the targets so that projectiles that miss the targets become embedded in the berm and do not strike unintended objects or persons. Projectiles can also become embedded in the ground beneath or around the target.
Some projectiles have been made and continue to be made with lead. As a result, the ground at firing ranges is often contaminated with lead.
The discussion above is merely provided for general background information and is not intended to be used as an aid in determining the scope of the claimed subject matter. The claimed subject matter is not limited to implementations that solve any or all disadvantages noted in the background.
An apparatus for separating material includes a frame and a rotatable sleeve supported by the frame. The sleeve has a first end, a second end, and a wall with a plurality of apertures to permit material smaller than a first size to fall through the apertures. A source of forced air is arranged to force air through an interior of the sleeve.
A ball screen apparatus includes a rotatable sleeve having a material introduction opening and a side wall with a plurality of apertures forming a screen. The plurality of apertures are sized to permit material smaller than a first size to fall through the plurality of apertures. A plurality of balls is located within an interior of the rotatable sleeve. A source of forced air is arranged to force air through the interior of the rotatable sleeve.
A method of recovering material includes: placing material within a ball screen comprising sleeve having a plurality of apertures and a plurality of balls within an interior of the sleeve; rotating the ball screen to crush portions of the material to a size that allows the crushed material to pass through the plurality of apertures; and discharging material remaining in the ball screen from the ball screen.
In a further embodiment, an assembly is provided that includes a ball screen having a material introduction end and an opposing material exit end and having a screen surface between the material introduction end and the material exit end. The ball screen is configurable to crush some material between the material introduction end and the material exit end to produce crushed material that falls through the screen surface and to press other material without crushing the other material, which exits the material exit end.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Embodiments described below provide a system for separating malleable material, such as lead, from other materials found at a firing range such as paper wading, sticks, grass, rocks, and dirt. Once separated, the malleable material can be collected and recycled.
Once system 100 has been positioned at the firing range, it is stabilized by using trailer dollies, such as trailer dolly 106, and downriggers, such as downriggers 108 and 110.
System 100 includes a number of hydraulic motors and pistons that are driven by hydraulic oil. A diesel engine 112 drives hydraulic pumps 113 to pressurize the hydraulic oil. A hydraulic oil reservoir 114 contains an extra supply of hydraulic oil, and a hydraulic oil cooler 118 cools the hydraulic oil. Valve bodies 116, which are controlled by electronics in a control panel 120, direct the hydraulic oil to the various motors and pistons to thereby control the speed at which the motors turn and to control the extent that the pistons are expanded or contracted. The speeds of the various motors may be controlled independently of each other and are set by control panel 120 to ensure a continuous flow of material through system 100 without material spilling from the components of system 100.
Material from the firing range is dumped into hopper 122 using earth moving machinery such as a front-end loader or excavator. Hopper 122 includes an open bottom that is positioned over hopper conveyor 124. Material placed in hopper 122 is carried upward by hopper conveyor 124 and over an end 125 where it pours into a crusher 126. Crusher 126 includes a plurality of rotating, spaced teeth that crush rocks and other hard material into smaller pieces. These smaller pieces pass into trammel screen 128, which includes a rotating sleeve having one or more screens. The sleeve rotates within an outer frame and is pitched at an angle that causes the material to move from an entrance 127 (
Ball screens 132 and 134 are connected to respective fans 142 and 143 by air conduits such as air conduit 144. As described further below, each ball screen 132/134 includes an interior rotating sleeve formed of a screen or perforated material and containing freely moving, crushing objects such as a plurality of stainless steel balls. As the sleeve is rotated, the freely moving objects move up along the side of the sleeve and then fall down upon the material introduced into a material introduction end 133. As the freely moving objects fall, the objects crush the material into smaller pieces. These smaller pieces fall through the screen material of the sleeve and onto smalls conveyor 136, which runs below ball screens 132 and 134. The material on smalls conveyor 136 is provided to a pivoting discharge conveyor 138, which is pivoted from side-to-side while material discharges at an end 139 to provide a pile of cleaned material that can be returned to the firing range. Fans 142 and 143 blow air through the air conduits, such as air conduit 144 and into ball screens 132 and 134. The airstream passes through the screen material of the sleeve and causes light material such as sticks, garbage, and paper wading to be blown out of the ball screens through the material introduction end 133.
When all the light material has been blown out of material introduction end 133 and all of the crushable material has been crushed into fine-enough particles to fall through the screen of the sleeve, the only material remaining in ball screens 132 and 134 is malleable material that, instead of being crushed, is pressed or otherwise deformed by the freely moving objects. This malleable material is too large to pass through the apertures in the screens of the ball screens. To remove this material from the ball screens, gates at a material exit end 135 are opened to provide discharge openings that are larger than the openings in the screen but smaller than the smallest freely-moving object (e.g., steel ball) contained in the ball screen. As the sleeve rotates, the malleable material, such as lead, travels toward material end 135 and exits through the openings and onto a malleable material conveyor 140. Malleable material conveyor 140 directs the malleable material to containers (not shown) at the sides of trailer 102. Thus, the malleable material, such as lead, is separated from the crushable material and the light-weight material found on the firing range to thereby recover the lead material from the firing range and recover the lead for safe disposal or for reuse.
Hopper conveyor 124 includes a conveyor belt 304, which rolls over rollers, such as rollers 308 and 310 that are supported by a conveyor frame 312. A hydraulic conveyor motor 306 drives conveyor belt 304 in a direction 314. As shown in
Crusher 126 includes a rotating cylinder 601 (
As the material moves through trammel screen 128, material smaller than the apertures in rotating screen 606 fall through the screen and are directed by funnel 511 onto conveyor belt 136. As a result, only material that is larger than the apertures in rotating screen 606 passes out exit end 129 through spout 514.
As shown in
A sleeve 730 extends between entrance cylindrical support 726 and exit cylindrical support 728. Sleeve 730 comprises a sleeve surface or screen surface 732 and one or more sleeve supports such as sleeve supports 735 and 737, shown in
Within sleeve 730, freely moving objects 738, also referred to as crushing objects, are carried up screen surface 732 by the rotation 736 of sleeve 730 and friction between the sleeve and the objects. As the freely moving objects move up the sides of sleeve 730, they eventually fall back toward to the bottom of sleeve 730 thereby crushing material as they fall. Freely moving objects 738 are constructed as metal balls in some embodiments, but may be constructed from any desirable material including rubber, flint pebbles or ceramic. Further, freely moving objects 738 may have any desired shape. In accordance with one embodiment, freely moving objects 738 are 1-3.5 inches in diameter. In other embodiments, freely moving objects 738 have other sizes. Freely moving objects 738 may all have the same size or have a plurality of different sizes. Freely moving objects 738 break some of the material introduced through the material introduction end into a plurality of smaller pieces while deforming other material introduced through the material introduction end without breaking the other material into a plurality of smaller pieces.
Ball screen 134 can be pivoted vertically along a pivot 740 using hydraulic pistons 742 and 744 that are attached near material introduction end 733. Hydraulic pistons 742 and 744 act as adjustable supports attached to the outer frame such that an inclination angle between screen surface 732 of sleeve 730 from first end 733 to second end 729 and a horizontal plane can be changed by adjusting the adjustable supports 742 and 744. As a result, material introduction end 733 may be moved in a vertical direction 746 relative to material exit end 729 thereby causing material introduced through material introduction end 733 to move toward material exit end 729 where it can be crushed by freely moving objects 738. The degree to which material introduction end 733 is lifted relative to material exit end 729 is controlled through control panel 120. The speed at which sleeve 730 is rotated is also controlled by control panel 120 through motor 710.
Two air conduit ports 748 and 750 are provided in dust guards 706 and 705, respectively, and are coupled to conduits such as air conduit 144 to channel air blown by fan 143 through screen surface 732, into the interior of sleeve 730, and out from opening 731 in an air flow direction 751. Air flow direction 751 includes a vertical component designed to lift light-weight material and a lateral component designed to push the light-weight material toward opening 731. The air flow through air conduit ports 748 and 750 is sufficient to blow light-weight material out of opening 731.
Material exit end 729, as best shown in
When the gates are moved to the open position, the smallest dimension 798 of the openings is larger than the apertures in screen surface 732. Thus, material that is too large to pass through screen surface 732 is permitted to pass through openings 762, 764, 766, 768, 770 and 772. As a result, material that is not crushed by the freely moving objects 738 but instead is pressed due to its malleability, is allowed to exit through material exit end 729 via the openings. This malleable material can include, for example, lead. The largest dimension of the openings formed by the gates is slightly smaller than the smallest freely moving objects 738 in order to prevent these objects from passing through the openings.
At step 1208, larger material that cannot fall through the trammel screen is dropped onto swivel conveyor 130 through spout 514 of trammel screen 128. Swivel conveyor 130 provides the material to one of the two ball screens 132 and 134 in an alternating manner. In accordance with one embodiment, swivel conveyor alternately fills each ball screen 132 and 134 to a maximum capacity at which the ball screen can still operate. At step 1210, ball screens 132 and 134 use motor 710 to rotate sleeve 730 thereby causing freely moving objects in the ball screen to crush non-malleable material into smaller pieces that fall through the screen surface 732. At the same time, the freely moving objects press malleable pieces while blowing lighter material out of opening 731 using air conducted through air conduction ports 748 and 750. When substantially all of the non-malleable material has been crushed and has exited through screen surface 732 and substantially all light-weight material has been blown out of opening 731, gates 774, 776, 778, 780, 782 and 784 are moved to create openings 762, 764, 766, 768, 770 and 772. Sleeve 730 is rotated while the gates are in the open position thereby causing the malleable material to exit through the openings and onto recovery conveyor 140. Note that the openings are sized such that freely moving objects 738 cannot exit through the gate openings.
At step 1214, the recovery conveyor drops the malleable material into a recovery container. At step 1216, when the malleable material has exited through the openings, the gates are reclosed at step 1216 and the method returns to step 1208 where the swivel conveyor provides new material to the ball screen.
Thus, hopper 122, crusher 126, and trammel screen 128 operate in a continuous mode while ball screens 132 and 134 operate in alternating batch modes, for example. While one of ball screens 132 and 134 is being filled with material, the other of ball screens 132 and 134 is completing the crushing of its material and later is having its handles moved to create openings 762, 764, 766, 768, 770 and 772 so that malleable material exits the ball screen. The rate at which material is conveyed by conveyors 124 and 130 and by trammel screen 128 is controlled to maximize the throughput of ball screens 132 and 134 while not exceeding the material handling capacity of ball screens 132 and 134 when those ball screens are operated in batch mode.
The speed of rotation of trammel screen 128 and of sleeve 730 of ball screens 132 and 134 may be adjusted based on the material and on the size of the freely moving objects 738 to maintain a high rate of crushing in the ball screens and to allow a high flow rate of material through the screen surfaces.
Although elements have been shown or described as separate embodiments above, portions of each embodiment may be combined with all or part of other embodiments described above.
Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms for implementing the claims.
This application claims priority to and is a divisional of U.S. patent application Ser. No. 14/802,428, filed Jul. 17, 2015 and incorporated herein by reference in its entirety.
Number | Date | Country | |
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Parent | 14802428 | Jul 2015 | US |
Child | 16133079 | US |