This invention relates generally to material handling. More specifically, this invention relates to a system particularly suited for material handling for long objects such as rails in low profile environments such as mines.
Mines frequently require low profile equipment and operations. To remove large quantities of materials, mines often utilize track systems that are very similar to track systems found above ground for railroads. These track systems have long steel rails laid end to end and in parallel with the parallel set of rails connected by a series of cross ties to form the rail tracks. The cross ties are usually wood, but can be of other material as well. Cars run on these track systems to remove mine material from the mine as well as to move equipment about the mine. While the track systems are very useful, the steel rails are quite heavy and installing the track systems in the restrictive confines of the mine can be extremely labor intensive as well as dangerous. The installation of the track systems requires manual handling of the steel rails, and because of their length and weight, this is extremely difficult work. The weight of the rails can lead to injuries just from moving the rails, let alone should control of the rail be lost and a person be trapped, or pinched, in some manner by the rail. Other elongated materials such as pipes, roof supports, and conduits are also moved in and out of mines. The several embodiments of the instant invention address issues of manual loading and unloading of heavy objects in confined environments.
U.S. Pat. No. 4,571,825 by Skibsted is for a “Railroad track removing apparatus”. The invention of Skibsted provides an apparatus for removing railroad track, comprising an elongated frame arranged to straddle a pair of rails and having elongated skids arranged to sit upon and slide along the ends of ties secured to the rails on the outboard sides of the rails, a rail and tie separating assembly mounted on the frame for separating lengths of rail from the ties to which the lengths of rail are secured, a rail elevating assembly for lifting lengths of rail which has been separated by the rail and tie separating assembly, and a conveyor for receiving a length of rail lifted by the elevating assembly and longitudinally transporting the rail to one end of the frame.
U.S. Pat. No. 1,255,193 by Madden et al. is for a “Rail Layer”. Madden provides a frame that is at least partially adapted to roll on rails. A part of the frame extends out over the side of the tracks and a hoist can ride out over the extended part of the frame to overhang outside the track where the hoist can pick up rails and carry them to the side of the track. The hoist picks up rails that have already been positioned near the track.
U.S. Pat. No. 2,671,414 by Moe is for a “Rail Re-Layer”. Moe is similar to Madden but provides an onboard power source to power a hoist as well as to propel the Rail Re-Layer. The Rail Re-Layer has an endless track that is positioned in the bed of the rail track and the onboard power source drives the endless track to move the Rail Re-Layer. In some applications, the Rail Re-Layer has a wheel associated with the endless track that can ride on a rail. In those applications, that wheel is driven and that is what moves the Rail Re-Layer.
U.S. Pat. No. 6,375,402 by Hertelendi et al. is for an “Apparatus for Unloading Rails”. An apparatus for unloading rails from a freight car on which the rails are arrayed to extend in a longitudinal direction of the freight car comprises a track-bound car, and a rail guiding unit positioned at each car end. Each rail guiding unit comprises a pair of rail guide heads having guide rollers for centering a respective one of the rails therebetween. The rail guide heads of a first rail guiding unit are positioned at one of the car ends and are displaceable in a horizontal plane perpendicularly to the longitudinal direction, and drives are provided for vertically adjusting the rail guide heads of the first rail guiding unit.
As may be seen from review of the above prior art, the prior art is not adapted to work in low profile environments such as mines like the several embodiments of the present invention. That and other advantages of embodiments of the present invention will be understood in light of the following descriptions of embodiments. While several embodiments are described, these are not the only embodiments within the scope of this invention and the described embodiments should not be considered as limiting the scope of the application.
Before discussing embodiments of the invention in summary or detail, a note is made to avoid confusion for those already familiar with mining. The term “shuttle car” is often used in mining for cars that move coal or other mined material from its extraction point to a conveyor which moves the material out of the mine. In this application and in the following description, the term “shuttle car” does not have that meaning Rather, “shuttle car” is applied to an element of embodiments of the invention which moves back and forth to shift the position of objects being loaded or unloaded.
Flat cars are used to transport the steel rails for mine track systems and other objects in mines. Elements of the system attach to the flat car, or supply car, for unloading and loading objects, such as steel rails, within the mine. A shuttle car has one end of an extension element attached to it. The other end of the extension element attaches to the supply car or a staging car intervening between the shuttle car and the supply car. The extension element moves the shuttle car back and forth with respect to the supply car by extending and retracting. To unload an object, such as a rail, the shuttle car is brought into proximity to the supply car by retraction of the extension element, and the near end of the object is engaged to the shuttle car. The extension element then extends to move the shuttle car away from the supply car to draw the object from the supply car. Once the elongated object is drawn to length, it is lowered to the track bed. At both ends of the object, a lowering mechanism is employed to lower it. For the end at the shuttle car, the entire shuttle car may lower itself in order lower the object. For the end near the supply car, an additional lowering mechanism is employed to lower the object. To load an object when objects, such as rails, are being retrieved, the process is reversed.
In at least one embodiment of the system, the system is capable of detecting when a free end of an object has too nearly approached the front end of the supply car or staging car. This allows the system to shut down to prevent the free end of an object from being pulled off of the supply car or staging car and falling, possibly injuring a person, or causing other, less serious, damage. In one embodiment, a hinged plate is located at the leading edge of the last supporting surface and a switch is associated with the hinged plate. When the switch detects that the hinged plate has become loaded, the advance of the shuttle car is halted, so that the object is not pulled off of the supporting car. A lowering mechanism can then be employed to lower that end of the object, once the system is restarted. Other detection mechanisms may be employed in other embodiments.
Some embodiments may employ a manipulator to move objects about on the supply car so that the objects are properly positioned for engagement by the shuttle car. This manipulator may be mounted on the supply car, or in embodiments employing a staging car, the manipulator may be mounted on the staging car. In still other embodiments, the manipulator may be capable of traveling along the supply car or staging car and may even be transferable between the supply car and the staging car. This can be accomplished, for example, by mounting the manipulator to a rail or conveyor system. When a supply car and staging car are used, if the rail or conveyor system traverses the two cars, then the manipulator can travel between the two cars. In embodiments where the manipulator is capable of travel, the end of the extension element opposite to the shuttle car may also travel with respect to the supply car or staging car. For example, that end of the extension element may also travel along a track and may even attach to the manipulator. This would allow the back and forth motion of the manipulator and shuttle car to be synchronized.
One type of a rail manipulator is a crane. A crane can attach to the objects and lift or pull the objects to manipulate them into position to be engaged by the shuttle car, or to receive the objects from the shuttle car and store them on the supply car. In embodiments employing a staging car, the crane can position the objects on the staging cars. The crane can also function as the lowering mechanism and lower or raise the ends of objects opposite to the shuttle car. Another, perhaps simpler object manipulator, would be a winch. If the winch is located on the staging car or supply car, the winch can pull objects to desired locations for attachment to the shuttle car. As with a crane, a winch may also function as a lowering mechanism. Some embodiments, however, may locate a winch as an object manipulator on the shuttle car itself. In those embodiments, the cable of the winch can be engaged to an object, such as a rail, and the winch can pull the object to the shuttle car. When the shuttle car is already separated a distance from an associated staging car or supply car by an extension element, the use of a winch located on the shuttle car can reduce the distance that a shuttle car needs to travel to draw an object off of the associated car.
The supply car and the staging car have wheels adapted to roll on the steel rails of the track system. However, the shuttle car has wheels on it which are intended to roll on the ground or floor of a mine shaft. If the system is being used to install a track system, the supply car and staging car will roll on rails that have already been laid. If the system is being used to take up a track system, the supply car and staging car will roll on rails that have not yet been retrieved. The shuttle car has a steering mechanism which allows it to be directed when it is being moved back and forth with respect to the supply car.
When the material handling system is being used to handle long objects, such as railing for example, a steel rail lying on the supply car is moved forward to a position where it can be engaged by the shuttle car. In embodiments employing a manipulator, the manipulator is used to move the rail. In embodiments employing a staging car, at least part of the rail will be placed on the staging car. The rail is then engaged by the shuttle car and the extension element, which has been retracted to bring the shuttle car into position, is extended to move the shuttle car away from the supply car to draw the rail out most of its length. Some embodiments are equipped with an emergency stop which detects if the free end of the rail is approaching the edge of its last support and stops the progress of the shuttle car to prevent the rail from being pulled off of its support.
The end of the object still on the supply car or staging car can be engaged by a lowering mechanism, if need be, and both ends are lowered to the floor of the mine; one end by the shuttle car and the other end by the lowering mechanism. Some embodiments do not required specific engagement of the rail by a lowering mechanism. For example, one lowering mechanism consists of a cross bar at the edge of the supply car or staging car that rises up and down. When the rail is drawn to length, its trailing end is brought to rest on the crossbar. Other embodiments may utilize a lowering mechanism such as a crane to lower the trailing end of the rail to the floor of the mine. In that case, the cable of the crane has to be attached to the rail to lower that end of the rail. To allow the carriage of the shuttle car to have contact with the selected rail, the telescoping boom of the shuttle car is in its retracted state which brings the carriage of the shuttle car into position next to the crane car. There the shuttle car can be coupled to the steel rail.
In at least one embodiment, the shuttle car lowers itself to lower its end of the object to the mine floor. To accomplish this, one embodiment of the shuttle car has two wheels. Each wheel is at the end of pivoting arms which pivot about points on the shuttle car. To lower the shuttle car, the pivoting arms rotate upward, allowing the shuttle car to settle. To lift the shuttle car the pivoting arms rotate downward, which drives the shuttle car upward.
The distance of travel by the shuttle car is determined by the maximum extension capabilities of the extension element. If the extension element is capable of extending the full length of a rail, typically 30 feet, then a rail may be completely drawn from the supply car or staging car by a single extension of the extension element. However, if the extension elements capabilities are less than the length of the rail, then the shuttle car needs to draw a rail partially off the rail or staging car, disengage the rail, return to nearer the supply or staging car, reengage the rail, and extend to finish drawing the rail from the supply or staging car. The rail can then be lowered, as previously described. Objects of other lengths will affect the operation of the material handling system similarly.
In
Referring now to
Shuttle car 20 can be steered as it is moved back and forth from supply car 90. Extension element 40 is pivotally connected at steering pivot 26 to frame 23 of shuttle car 20. The pivot connection at steering pivot 26 allows the angle of shuttle car 20 with respect to extension element 40 to change. Steering cylinder 44 is pivotally connected at one of its ends to the side of extension element 40 and at its other end to frame 23 of shuttle car 20. Varying the length of steering cylinder 44, varies the angle of shuttle car 20 with respect to extension element 40. By varying the angle of shuttle car 20 as it is extended or retracted, its direction can be affected.
Track 51 on staging car 50 aligns with, and is complementary to, track 91 on supply car 90 which allows trolley 53 to pass back and forth between staging car 50 and supply car 90 where crane 70 can acquire rails 1010 to move them onto staging car 50. In the embodiment shown in
Crane 70 has a boom 71, boom cylinder 72, cable 73, cable drum 74, and base 75 among other features. Boom cylinder 72 extends and retracts to raise and lower boom 71. Cable drum 74 lets out and takes in cable 73. The end of cable 73 is attached to a rail to engage it and manipulate its position. Crane 70 can swivel to either side of tracks 51 and 91, and when being used as a lowering mechanism, can be set up so that it can extend over the forward edge of staging car 50 so that it can lower its end of an object down to the mine floor.
It has been previously noted that a winch might also serve as a rail manipulator, or as a lowering mechanism, or both. Returning to
In
Similar to other embodiments of material handling system 10, the embodiment of
Once shuttle car 420 and crane 470 have engaged a rail, trolley 453 moves along track 491 to move crane 470 and shuttle car 420 and move the rail off of supply car 490. Once the rail is moved beyond supply car 490 and or staging car 450, to lower the rail to the mine floor, shuttle car 420 lowers itself to lower the rail and crane 470 lowers the rail using its boom or by paying out cable. In this embodiment, crane 470 acts as both an object manipulator and object lowering mechanism. Depending on the extension capabilities of telescoping extension element 440 or how shuttle car 420 engages the rail, staging car 450 may not be needed.
Once anchor 684 is fixed in position, extension element 640 can be extended and retracted to move shuttle car 620 back and forth with respect to the opposite, fixed end of extension element 640. In
Object manipulators 627 are mounted on the top of shuttle car 620. In the embodiment of
At opposing sides of shuttle car 620, wheels 621 are mounted at the ends of swing arms 622. Swing arms 622 attach to frame 623 of shuttle car 620 at frame pivots 624. Vertical adjustment actuator 632 is coupled between swing arm 622 and frame 623 and moves swing arm 622 with respect to frame 623. In the embodiment of
Cross bar 661 of object manipulator 660 is mounted to internal sleeve 683 of second extension element 680. Actuator mounts 662 are fixed to each end of cross bar 661 and support actuators 663 which are fixed at their base at one end. Opposite to the fixed bases of actuators 663 are rods carrying pulleys 665 in engagement with tensile members 664. Tensile members 664 are fixed at one end to brackets 666, pass around pulleys 665, and reverse direction to pass over pulleys 667 at the front ends of actuator mounts to drop vertically. Grapples 669 affix to the ends of tensile members 664. In the embodiment of object manipulator 660 shown in
Auxiliary object manipulator 685 is mounted to the top of external sleeve 681 of second extension element 680. Auxiliary object manipulator 685 provides the capability to retrieve objects that are located laterally from material handling system 610. This is particularly useful when material handling system 610 is being used to retrieve objects in an area as opposed to unloading objects from a supply proximal to material handling system 610.
In
In the embodiments of material handling system 610 shown in
In the embodiment of shuttle car 620 shown in
The various moving elements of the several embodiments discussed may be powered by any common power source. For example, the shuttle car can raise and lower its wheels and steer by hydraulic cylinders which are powered by a motor and hydraulic pump. Similarly, for embodiments of the extension element that are telescoping extension elements, they may be powered by one or more hydraulic cylinders. However, other linear actuators such as lead screws driven by electric motors may be employed as well may be cable arrangements in some embodiments. The rail lowering mechanism and rail manipulator may be hydraulically powered or may be electrically power. For example, a winch will likely be electrically driven, while a crane will likely be at least partially electrically driven. Movement of the trolley on which a rail manipulator rides may be accomplished by a cylinder, particularly a hydraulic cylinder, or by a cable or chain loop driven hydraulically or electrically.
In addition to variation among types of extension elements, motive units, rail lowering mechanisms, and rail manipulators, embodiments of the material handling system may vary by the number of cars employed. Some embodiments may employ a shuttle car attached to a staging car by an extension element, wherein a supply car is interchangeably connected to the staging car. As one supply car is emptied, or filled, it may be disconnected to make room for another supply car. In this embodiment, several supply cars with minor or no modification could service the slowly moving jobsite where the shuttle car, extension element, and staging car combination are located. Other embodiments may employ a shuttle car attached directly to a supply car by an extension element. While this embodiment is simpler, it does not have the advantage of changing out the car that carries the supply of objects.
It is to be understood that the embodiments and claims are not limited in application to the details of construction and arrangement of the components set forth in the description and illustrated in the drawings. Rather, the description and the drawings provide examples of the embodiments envisioned, but the claims are not limited to any particular embodiment or a preferred embodiment disclosed and/or identified in the specification. The drawing figures are for illustrative purposes only, and merely provide practical examples of the invention disclosed herein. Therefore, the drawing figures should not be viewed as restricting the scope of the claims to what is depicted.
The embodiments and claims disclosed herein are further capable of other embodiments and of being practiced and carried out in various ways, including various combinations and sub-combinations of the features described above but that may not have been explicitly disclosed in specific combinations and sub-combinations. Accordingly, those skilled in the art will appreciate that the conception upon which the embodiments and claims are based may be readily utilized as a basis for the design of other structures, methods, and systems. In addition, it is to be understood that the phraseology and terminology employed herein are for the purposes of description and should not be regarded as limiting the claims.
This application claims priority from U.S. Provisional Application 61/440,953, filed on Feb. 9, 2011. The teachings in the specification and drawings for U.S. Provisional Application 61/440,953 are incorporated herein by reference.
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Number | Date | Country | |
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