1. Field of Invention
This invention relates to hard material disintegration machines, and more particularly to a portable rock crusher and scarifier having a rotating arbor adaptable to crush, grind, scarify and mill material in-situ and on-site for building, maintaining, and reconditioning roadways and for road site development.
2. Background and Description of Prior Art
Rock crushers and scarifiers are essential for building, maintaining and reconditioning roads but have various inherent drawbacks including rapid arbor and tooling implement wear, they are either mobile or stationary but are generally not operable in both configurations, they have limited tooling implement mounting patterns and they typically cannot mill surfaces to depths below the surrounding frame structure.
Stationary rock crushers, even those that are movable, require material be transported from a source to the rock crusher for crushing, and thereafter the finished product must be transported to a use site, usually with dump trucks and the like. Two way transport of the raw and finished material increases costs, decreases efficiency and requires additional road maintenance equipment.
Mobile rock crushers may have various configurations including large highly specialized machines that move on crawler tracks or on rubberized wheel assemblies, and smaller vehicle supported machines. Large mobile rock crushers typically carry a rotating arbor having a plurality of tooling implements thereon at a position between the crawler track assemblies and the arbor is generally permanently interconnected with an integral power source. Smaller vehicle supported rock crushers are known to have an integral power source forward of a rotating arbor which places the machine's center of gravity forwardly necessitating large support vehicles to counteract the weight and leading to limited operator visibility which increases risk of accidents and injury.
Known stationary rock crushers and known mobile rock crushers are designed for crushing fractureable material such as rock and gravel and the like but are not well suited for the milling operations without undergoing significant customization. Further, known stationary and mobile rock crushers typically have a fixed geometry that limits how the machine is used, what type of raw material may be crushed and the characteristics of the finished product, such as size.
What is needed is a portable rock crusher and scarifier that reclaims, recycles, converts and mills a wide variety of materials in-situ. The apparatus must be attachable to a variety of road maintenance vehicles and be able to effectively mill and plane asphalt, concrete, and bedrock, crush and pulverize rocky material, as well as scarify surfaces and prepare roadbeds. Further, because not all materials can be crushed, pulverized, milled, or ground in the same way, the apparatus must be easily adjustable and adaptable to the particular site needs by changing impact tooling, arbor rotation and product sizing distances.
Our portable rock crusher and scarifier overcomes various of the aforementioned drawbacks and resolves various of the aforementioned needs by providing a rock crusher and scarifier that may be used in both mobile and stationary operations.
Our portable rock crusher and scarifier has a crusher frame defining a feed inlet, a discharge outlet and a crusher channel extending therebetween. An anvil weldment channel communicating with the crusher channel carries an anvil weldment having two adjacent vertically spaced anvils to enhance durability and the anvil weldment is adjustably positionable in the anvil channel to regulate the size of finished product. A rotating arbor defining plural “V” shaped axial keyways for mounting tooling implements is journaled by the crusher frame and extends transversely across the crusher channel. The arbor keyways each define plural spacedly arrayed threaded holes to engage with threaded connectors extending through the tooling implements and radially into the arbor. A power pack releasably connected to the crusher frame and operatively communicating with the arbor is carried spacedly rearward above the arbor to move the center of gravity rearward and improve operator visibility. Our portable rock crusher and scarifier is releasably mountable to a variety of road maintenance vehicles which provide the required forward movement to force-feed the rock crusher position the rock crusher and scarifier in an orientation allowing an operator to access and maintain the arbor as well as change tooling implements on-site, to adapt the rock crusher and scarifier to the on-site material being recycled and reclaimed. A canting mounting structure between the carrying vehicle and the power pack allows our rock crusher and scarifier to be canted, during operation, to maintain the side-to-side angulation of a roadway relative to horizontal which is known in the industry as the “super elevation” or “super” of the roadway.
Our invention does not reside in any one of the identified features individually but rather in the synergistic combination of all of its structures, which give rise to the functions necessarily flowing therefrom as hereinafter specified and claimed.
A portable rock crusher and scarifier generally provides a crusher frame defining a crusher channel with a feed inlet, a discharge outlet and an anvil weldment channel carrying a height adjustable anvil weldment with plural anvils, and journaling a reversibly rotatable arbor defining plural symmetrically spaced axial keyways for releasable radial mounting of tooling implements. A power pack having an engine and a hydraulic pump is operatively connected to the arbor and a canting mounting structure releasably attaches the portable rock crusher and scarifier to a road maintenance vehicle.
In providing such an apparatus it is:
a principal object to provide such a portable rock crusher and scarifier for in-situ crushing, grinding, pulverizing, milling, reclamation and recycling of materials for building, maintaining and restoring roadways and for the preparation of roadbeds.
a further object to provide such a portable rock crusher and scarifier that is adjustable in geometry, speed and tooling to adapt to the on-site material being recycled and reclaimed.
a further object to provide such a portable rock crusher and scarifier having a reversible rotatable arbor defining plural symmetrically spaced “V” shaped axial keyways to automatically center and retain tooling implements.
a further object to provide such a portable rock crusher and scarifier having an arbor defining a plurality of spacedly arrayed threaded radial blind holes in the arbor keyways for mounting various patterns and configurations of tooling implements.
a further object to provide such a portable rock crusher and scarifier having a power pack carried rearward of the crusher frame to increase operator visibility, to move the center of gravity rearward and to allow carriage by a variety of road maintenance vehicles.
a further object to provide a portable rock crusher and scarifier that may be used in both mobile and stationary configurations.
a further object to provide such a portable rock crusher and scarifier defining an anvil weldment channel communicating with the crusher channel and carrying an adjustably positionable anvil weldment having plural anvils.
a further object to provide such a portable rock crusher and scarifier having a power pack that is adjustably positionable relative to the crusher frame and removable therefrom.
a further object to provide such a portable rock crusher and scarifier for tooling implements that extend below the crusher frame for milling, planning and scarifying to depths below the crusher frame.
a further object to provide such a portable rock crusher and scarifier that produces quality aggregate from a wide range of materials that exist on-site.
a further object to provide such a portable rock crusher and scarifier that is adaptable to grind, mill and plane road surfaces and roadbeds.
a further object to provide such a portable rock crusher and scarifier having a canting mounting structure for maintaining the super of the roadway.
a further object to provide such portable rock crusher and scarifier that may be force-fed and be gravity fed.
a still further object to provide such a portable rock crusher and scarifier that is of new and novel design, of rugged and durable nature, of simple and economic manufacture and one that is otherwise well suited to the uses and purposes for which it is intended.
Other and further objects of our invention will appear from the following specification and accompanying drawings which form a part hereof. In carrying out the objects of our invention it is to be understood that its structures and features are susceptible to change in design and arrangement with only one preferred and practical embodiment of the best known mode being illustrated in the accompanying drawings and specified as is required.
In the accompanying drawings which form a part hereof and wherein like numbers refer to similar parts throughout:
As used herein, the term “bottom”, its derivatives, and grammatical equivalents refers to the portion of our portable rock crusher and scarifier that is closest to a supporting surface, such as a road bed. The term “top”, its derivatives, and grammatical equivalents refers to the portion of our portable rock crusher and scarifier that is most distant from the supporting surface. The term “rearward”, its derivatives, and grammatical equivalents refers to the portion of our portable rock crusher and scarifier that is closest to a carrying vehicle. The term “forward”, its derivatives, and grammatical equivalents refers to the portion of our portable rock crusher and scarifier that is most distant from the carrying vehicle. The term “outer”, its derivatives, and grammatical equivalents refers to a side portion of our portable rock crusher and scarifier as opposed to a laterally medial portion.
Our portable rock crusher and scarifier 9 generally provides canting mounting structure 16 carrying power pack 10 that is releasably attachable to crusher frame 11 journaling rotatable arbor 12 having plural tooling implements 13.
The canting mounting structure 16 (
The primary frame 110 is formed of end-to-end interconnected steel beams and has a top portion 111, a bottom portion 112, and two spaced apart side portions 113a, 113b. Reinforcing beams 114 extend from upper lateral corner to the opposing lower lateral corner adding structural rigidity to the primary frame 110. The reinforcing beams 114 intersect at medial hub 115 where the forwardly extending axle 127 is carried. Secondary supports 116 extend radially from the hub 115 and communicate with the top portion 111 and bottom portion 112. Carrying vehicle mounts 117 are structurally carried by the primary frame 110 opposite the secondary frame 120 and extend from the top portion 111 to the bottom portion 112 providing a releasable means for attachment to a carrying vehicle 100 such as a skid steer vehicle (
The secondary frame 120 is similarly formed of end-to-end interconnected steel beams and has a top portion 121, a bottom portion 122, and two spaced apart side portions 123a, 123b. Reinforcing beams 124 extend from upper lateral corner to the opposing lower lateral corner adding structural rigidity to the secondary frame 120. The reinforcing beams 124 intersect at a medial hub (not shown) where the forwardly extending axle 127 engages with the secondary frame 120. Secondary supports 126 extend radially from the medial hub (not shown) and communicate with the top portion 121 and bottom portion 122.
Plural horizontally spaced intermeshing opposing arcuate supports 129 are structurally carried on the forward portion of the primary frame 110 and on the rearward portion of the secondary frame 120 extending from the top portions 111, 121 to the bottom portions 112, 122 respectively. The intermeshing arcuate supports 129 provide additional strength to the interconnection of the primary frame 110 and the secondary frame 120 while allowing the primary frame 110 and the secondary frame 120 to pivot relative to one another about the axle 127.
Hydraulic cylinder 128 communicates with the primary frame 110 and the secondary frame 120 at the bottom portions 112, 122, respectively thereof and operatively communicates with hydraulic pump 23 with known hoses and fittings (not shown). One end portion of the hydraulic cylinder 128 is pivotally interconnected to cylinder bracket 130 structurally carried by the secondary frame 120, and the opposing end portion of hydraulic cylinder rod (not shown) is pivotally interconnected to piston rod bracket 131 structurally carried by the primary frame 110. Extension and retraction of the hydraulic cylinder rod (not shown) cants the secondary frame 120, relative to the primary frame 110 about the axle 127. The canting of the portable rock crusher and scarifier 9 allows an operator to ensure the super of the roadway is maintained as the crushing, grinding, recycling and reclamation operation is ongoing. The canting of the portable rock crusher and scarifier 9 also enables an operator to prevent material from escaping crushing due to unintended excessive lean of the crusher frame 11 which may be caused by excess material agglomerating under one side portion of the crusher frame 11.
The power pack 10 comprises a U-shaped power pack frame 25 of plural structurally interconnected box beams and has a back portion and two spaced apart forwardly extending side portions 25a, 25b supporting an internal combustion engine 28 mechanically communicating with a hydraulic pump 23 by known means. In the preferred embodiment, the back portion of the powerpack frame 25 is the secondary frame 120 of the canting mounting structure 16. In an alternative embodiment (not shown), the back portion of the powerpack frame 25 may be a separate structure (not shown) directly connected to forward portion of the secondary frame 120.
The power pack 10 is releasably attachable to upper rearward portion of the crusher frame 11 with releasable fasteners 32 extending through aligned holes 30 defined in the power pack frame side portions 25a, 25b, opposite the secondary frame back portion 120, and also defined in first and second side portions 52, 53 respectively of the crusher frame 11. The releasable fasteners 32 allow the power pack 10 to be detached from the crusher frame 11 (
The crusher frame 11 is formed of steel plates and has a first side portion 52, a spaced apart parallel second side portion 53, a forward roof portion 48a, a rearward roof portion 48b and two spaced apart strongbacks 63, 64 perpendicular to the side portions 52, 53 and perpendicular to the roof portions 48a, 48b defining an anvil weldment channel 38 therebetween. The forward roof portion 48a, the strongbacks 63, 64 and the first and second side portions 52, 53 are structurally interconnected at adjoining edge portions such as by welding. The rearward roof portion 48b may be interconnected to the first and second side portions 52, 53 respectively and strong back 64 along adjacent edge portions by welding or may be secured thereto with removable pin-type fasteners (not shown). Crusher channel 51 extending from feed inlet 46 at forward end portion 11a to discharge outlet 47 at rearward end portion 11b is defined by the first and second side portions 52, 53 below the forward and rearward roof portions 48a, 48b respectively.
Each side portion 52, 53 structurally carries a reinforcing plate 31 on a side opposite the crusher channel 51 to support an arbor bearing mount 33. Skid plates 34 releasably fastened to bottom edge portions 52a, 53a provide a durable replaceable wear surface. Forward edge portions 52b, 53b of each side portion 52, 53 flare outwardly and work cooperatively with a forwardly inclined baffle 27 to direct material into the feed inlet 46. The baffle 27 and leading edge of the forward roof portion 48a form a somewhat pointed “bow” for the crusher frame 11 above the feed inlet 46 that assist an operator in maintaining a proper path of travel along a linear pile of material being recycled. Debris scuppers 36 are defined in each side portion 52, 53 above the forward roof portion 48a and spacedly forward of strongback 63 to prevent materials from accumulating on top of the forward roof portion 48a. The debris scuppers 36 also provide attachment points for lifting the crusher frame 11.
A safety curtain 45 of plural lengths of rubber belt, or similar flexible material, depends from underside of the forward roof portion 48a inside the crusher channel 51, proximate to feed inlet 46, to prevent material from being thrown forwardly and outwardly through the feed inlet 46 by rotation of the arbor 12. Primary wear plate 50 is releasably fastened to the underside of the forward roof portion 48a forward of the arbor 12 providing a durable replaceable impact wear surface inside the crusher channel 51.
Deflector plates 49 extend between the first and second side portions 52, 53 spacedly above and spacedly rearward of the arbor 12 and are releasably attached to the rearward roof portion 48b. The deflector plates 49 absorb impacts from material being thrown upwardly and rearwardly by the rotating arbor 12 and deflect those materials downwardly behind the arbor 12. Flexible exit door 54, preferably formed of rubberized belt-type material, extends transversely across the discharge outlet 47 and depends from rearward edge of rearward roof portion 48 to help contain material, dust and debris inside the crusher frame 11 and simultaneously allow processed material to exit the crusher channel 51.
The anvil weldment channel 38 defined by the two spaced apart strongbacks 63, 64 is between the forward roof portion 48a and the rearward roof portion 48b and extends transversely between the side portions 52, 53. The anvil weldment channel 38 communicates with the crusher channel 51 spacedly above the arbor 12 and positionally maintains anvil weldment 17 therein. Plural horizontally spaced elongated holes 157 (
As shown in
Plural hydraulic rams 155 operatively interconnected with the hydraulic pump 23 are carried between the forward inertia plate 140 and the rearward inertia plate 144. The hydraulic rams 155 each have a piston rod 155a that extends and retracts axially responsive to inflow and outflow of pressurized hydraulic fluid. Each hydraulic ram 155 and each piston rod 155a defines an aligned axial hole (not shown) through which extends one of the threaded fasteners 153 extending through the elongated holes 157 defined in the strongbacks 63, 64 and through holes 154 defined in the inertia plates 140, 144. (
Friction enhancing panels 158 (
In a second embodiment annular spacing collars (not shown) each defining an axial through hole (not shown) and are carried by the threaded fasteners 153 between the forward inertia plate 140 and the rearward inertia plate 144 adding rigidity to the anvil weldment 17 and maintaining the distance between the forward inertia plate 140 and the rearward inertia plate 144 when the threaded fasteners 153 are tightened.
The anvil weldment 17 is carried in the anvil weldment channel 38 and is positionally adjustable therein by means of hydraulic rams 160. Hydraulic ram 160 communicates between hydraulic ram mounting bracket 161 carried by each side member 52, 53 adjacent upper edge of the anvil weldment channel 38 and with ram piston mounting yoke 156 carried by the anvil block 150 spacedly inward each lateral end portion so that hydraulic ram 160 is oriented generally vertically within the anvil weldment channel 38. The threaded fasteners 153 extending through the horizontally spaced vertically elongated holes 157 defined in the strongbacks 63, 64, through aligned holes 154 defined in the inertia plates 140, 144 and extending axially through the hydraulic rams 155 prevent the anvil weldment 17 from inadvertently changing position when pressurized hydraulic fluid is not being supplied to the hydraulic rams 155.
First anvil 40 and similar second anvil 41 are releasably fastened to anvil mounting surfaces 150a, 150b of the anvil block 150 with threaded anvil fasteners 152 extending downwardly through holes (not shown) defined in the anvil block 150 to engage with recessed threaded fasteners (not shown), such as plow bolts, carried in countersunk holes 98 defined in each anvil 40, 41. (
In the preferred embodiment, each anvil 40, 41 is comprised of plural elongate segments (
Hydraulic motors 26 are carried by the crusher frame 11 adjacent the side portions 52, 53 proximate the upper surface of the forward roof portion 48a and the forward strongback 63. Each hydraulic motor 26 operatively communicates with the hydraulic pump 23 by known means and carries a rotatable drive pulley 22 laterally outward of the adjacent side portion 52, 53 on a drive shaft (not shown) extending through a hole (not shown) defined in the adjacent side portion 52, 53.
The arbor 12 is an elongate rod-like member journaled by the crusher frame 11 extending transversely across the crusher channel 51. The arbor 12 defines an axle hole 55 in each end and plural symmetrically spaced “V” shaped axial key ways 57 for radial mounting of tooling implements 13. As shown in
A stub shaft 56 (
An axial through hole 59 is defined in each stub shaft 56 communicating between opposing end portions to release trapped air as the stub shaft body 56b is press-fitted into the axle hole 55. Injecting high-pressure grease into the hole 59 assists removal of the stub shaft body 56b and expansion collar 61 from the axle hole 55. An elongate threaded fastener 63, such as a bolt, is inserted into the axial through hole 59 which has a radially reduced shoulder (not shown) proximate inner end portion to threadably engaged with a threaded axial hole (not shown) defined in the arbor 12 inside of axle hole 55. The threaded fastener 63 ensures the stub axle 56 is completely seated inside the axle hole 55 before the expansion collar 61 is expanded. Annular sealing ring 64 fits over of the stub shaft axle 56a and protects outer surface of the expansion collar 61 from debris.
As shown in
Drive belt 21 communicates between the drive pulley 22 and the slave pulley 44 to transfer rotational motion of the drive pulley 22 to the arbor 12. Idler pulleys 43 keep the drive belt 21 in position. Ventilated belt guards 35 (
A control panel 99, that may be carried within operator cab of the carrying vehicle 100, is operatively connected to the engine 28, the hydraulic pump 23 and the hydraulic motors 26 enables the operator to control operation of the power pack 10 and the arbor 12 and the canting mounting structure 17.
As shown in
Holes 74 are defined in each tooling implement 13 each hole 74 having an enlarged counterbore 75 communicating with tooling implement head portion to carry a head portion (not shown) of a threaded releasable fastener (not shown) such as a bolt. The releasable fasteners (not shown) extend through the holes 74 defined in the tooling implement 13 and engage with one of the spacedly arrayed radial threaded holes 58 defined in the base portions 57c of the arbor keyways 57.
As shown in
As shown in
Having described the structure of our portable rock crusher and scarifier, its operation may be understood.
The power pack 10 is releasably attached to the crusher frame 11 by aligning the holes 30 defined in the power pack frame side portions 25a, 25b and the holes 30 defined in the side portions 52, 53 of the crusher frame 11 and installing releasable fasteners 32 therethrough. The hydraulic cylinders 19 communicating between the crusher frame 11 and the power pack frame 25 side portions 25a, 25b are interconnected and the appropriate hydraulic connections are made. The carrying vehicle 100 is positioned adjacent behind the primary frame 110 of the canting mounting structure 16 so that the carrying vehicle mounts 117 may be releasably connected to the carrying vehicle 100 by known means. Hydraulic and other operative connections are made so that the portable rock crusher and scarifier 9 and its functions may be controlled by the operator using the control panel 99 within the operator cab of the carrying vehicle 100.
The on-site and in-situ materials to be recycled, reclaimed, planed, milled or crushed are examined to determine the appropriate type of tooling implement 13 to install on the arbor 12.
Loosened rocky materials in linear piles, also known as windrows, are most effectively reduced “dry” with plural spacedly arrayed crushing implements 15 (
The carrying vehicle 100 is operated to lift the portable rock crusher and scarifier 9 vertically to a height sufficient for an operator to access the arbor 12 and tooling implements 13 thereon. Hydraulic cylinders 19 may also be actuated to rotate the forward end portion 11a of the crusher frame 11 upwardly (
The arbor 12 is visually inspected for damage and wear. Any debris within the keyways 57 is removed and a plurality of crushing implements 15 are installed on the arbor 12 in the keyways 57 in the configuration that is appropriate to the material being crushed, recycled and reclaimed. Threaded fasteners (not shown) inserted into and through the holes 74 defined in each crushing implement 15 engage in the threaded radial holes 58 defined in the keyways 57. The threaded fasteners (not shown) are tightened so that the head portions (not shown) fit into the counterbores 75 defined in the crushing implement 15 head portion. Arbor protector implements 18 are similarly installed to protect those portions of the arbor 12 not carrying crushing implements 15. (
The position of the anvils 40, 41 relative to the crushing implements 15, is adjusted to provide rotational clearance and to regulate the size of crushed product output. Pressurized hydraulic fluid inflow to hydraulic rams 155 is interrupted to reduce the surface friction between the adjacent surfaces of the strongbacks 63, 64 and the inertia plates 140, 144 and the aluminum panels 158 carried thereon. Hydraulic rams 160 are actuated to move the anvil weldment 17 vertically upwardly and downwardly within the anvil weldment channel 38 as desired. Pressurized hydraulic fluid is then reapplied to the hydraulic rams 155 to increase the surface friction between adjacent surfaces of the strong backs 63, 64, the inertia plates 140, 144 and the aluminum panels 158 carried thereon effectively locking the anvil weldment 17 in position.
A road grader or similar road maintenance vehicle is used to gather rocks and gravel and similar material from the road surface and from barrow pits on either side of the roadway and deposit the materials in a linear windrow on the roadbed. Additional material to be crushed may also be deposited on the roadway by dump trucks and the like.
The engine 28 is started using the control panel 99 in the operator cab of the carrying vehicle 100. The rock crusher and scarifier 9 is thereafter moved forwardly along the windrow by the carrying vehicle 100 with the windrow material entering the feed inlet 46. Forward movement along the windrow creates a wall of material to be crushed inside the crusher frame 11 immediately forward of the arbor 12. The most efficient rotational speed for the arbor 12 is dictated by the type of material being recycled and reclaimed and is adjusted by the operator using the control panel 99.
As the arbor 12 rotates, the crushing implements 15 repeatedly strike and cut into proximate side of the material wall (not shown) while additional material is simultaneously added to the distal side of the material wall. This action “force feeds” the rock crusher and scarifier 9 ensuring substantially continuous contact between the proximate side of the material wall and the crushing implements 15 on the arbor 12 wherein impact shock is transferred forwardly from the arbor 12 through the rocky material causing rock versus rock collisions. Rotation of the arbor 12 also causes tumbling of the rocky material generating additional rock versus rock collisions.
Material too large to pass between the crushing implements 15 and the primary wear plate 50 and between the crushing implements 15 and the anvils 40, 41 is fractured into smaller pieces as it wedges between the rotating and stationary surfaces. Material small enough to pass between the crushing implements 15 and the primary wear plate 50 and between the crushing implements 15 and the anvils 40, 41 is moved by the rotation of the arbor 12 to a rear portion of the crusher frame 11 whereupon the material may strike the deflector plates 49 and thereupon fall onto the supporting surface and exit the crusher frame 11 through the discharge outlet 47 and under the flexible exit door 54. Thereafter, the material may be handled as desired, such as being further dispersed upon the roadbed.
An alternative to the crushing implements 15 is milling implements 14 for grinding and milling asphalt, bedrock and concrete. Milling implements 14 have a greater vertical dimension than crushing implements 15 and require retraction of the anvil weldment 17 into the anvil weldment channel 38 to provide clearance for the arbor 12 rotation. (
Loosened bituminous and cement type material may be pulverized wet with crushing implements 15 rotating at approximately 4000-5000 feet per minute tip speeds. Patternation of the crushing implements 15 is commonly multi-helical inside out.
Firm, in place sections of solid asphalt, bedrock, concrete and the like are effectively milled with milling implements 14 rotating in either an upward or downward direction at approximately 1000 to 2000 feet per minute tip speed. Milling implements 14 may also be used for preparation of roadbeds.
When operated in a stationary configuration (
The base 101 is formed of plural structurally interconnected box beams 102 and may releasably support the portable rock crusher and scarifier 9 spacedly above the supporting ground surface with the crusher frame 11 positioned angularly relative to the power pack 10 and base 101 so that the feed inlet 46 is positioned higher than the discharge outlet 47. (
The foregoing description of our invention is necessarily of a detailed nature so that a specific embodiment of a best mode may be set forth as is required, but it is to be understood that various modifications of details, and rearrangement, substitution and multiplication of parts may be resorted to without departing from its spirit, essence or scope.
Having thusly described our invention, what we desire to protect by Letters Patent, and
This application claims the benefit of earlier filed U.S. Provisional Application No. 60/903,512 filed on Feb. 27, 2007.
Number | Date | Country | |
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60903512 | Feb 2007 | US |