1. Field
The present invention provides a rail system for a powered pallet conveyor. Moreover, the present invention provides a process for operating a switch of a rail system for a powered pallet conveyor. The present invention uses a switch means for switching between m alternative travel pathways, wherein m≧2, and allowing the vehicle to continuously move across the switch after switching.
Powered pallet conveyors are known. Powered pallet conveyors may be used for loading or unloading trucks and trailers with product on pallets or in containers. Powered pallet conveyors may comprise a vehicle and a rail system which defines pathways on which the vehicle may travel.
Conventional rail systems for a powered pallet conveyor may comprise switch means for allowing the vehicle to travel on alternative pathways. U.S. Pat. No. 4,498,399 discloses a free line switch arrangement for power-and-free trolley conveyors wherein the free line comprises two rails. Two other types of switch means have been considered, namely a quadro switch and a rotation switch.
A quadro switch, as shown in
A rotation switch, as shown in
Both switch means are unsatisfactory in that the vehicle cannot travel continuously across the switching means without stopping. As a consequence, the presence of a switching means results in a limitation of the maximum speed by which the powered pallet conveyor is capable of completing a task. Limitations imposed by the switching means are even greater in cases when more than one switching is required per travel of the powered pallet conveyor.
Furthermore, conventional switching means have significant space requirements. Moreover, vehicles subjected to frequent acceleration/deceleration suffer from increased wear and earlier failure so that maintenance costs are high.
It is the object of the present invention to provide a rail system for a powered pallet conveyor which allows the vehicle to travel continuously across the switching means without stopping while the switching means has reduced space requirements and does not subject vehicles to acceleration/deceleration during switching so that wear is reduced and early failure of the vehicle and high maintenance costs are avoided.
This problem is solved according to the present invention by a rail system for a powered pallet conveyor, which comprises alternative pathways for a vehicle traveling along an electric cable means provided on at least one of n parallel rail means defining a travel pathway, wherein n≧2, whereby the rail system is characterized by a switch means for switching between m alternative travel pathways, wherein m≧2, and allowing the vehicle to continuously move across the switch after switching, said switch means comprising
(a) a first actuating means for selectively positioning (m*n) rigid rail portions bridging the distance between rail ends optionally holding cable ends at
(i) n joining points where the n parallel rail means of each of the m alternative travel pathways subject to switching converge, and
(ii) (m*n) continuation points where each alternative pathway subject to switching diverges downstream from the joining points, and
(b) a second actuating means for selectively positioning [m(n−1)] rigid rail portions bridging the distance between rail ends optionally holding cable ends at crossing portions, where each alternative pathway subject to switching is discontinued downstream from the corresponding continuation points,
whereby the positioning of a set of n rigid rail portions by the first actuating means and the positioning of (n−1) rigid rail portions by the second actuating means provides a travel pathway allowing the vehicle to continuously travel across the switch along the electric cable means provided on at least one of n parallel rail means defining the travel pathway.
Moreover, the present invention provides a process for operating a switch of a rail system for a powered pallet conveyor according to the invention, which comprises the steps of
(a) selecting one of n alternative pathways;
(b) positioning n rigid rail portions for bridging the distance between
(i) n joining points where the m alternative travel pathways subject to switching coincide, and
(ii) n continuation points of the selected travel pathway downstream from the joining points,
(c) positioning n−1 rigid rail portions for bridging the distance between rail ends optionally holding cable ends at crossing portions where each alternative pathway subject to switching is discontinued downstream from the corresponding continuation points,
thereby providing the selected pathway allowing the vehicle to travel along an electric cable means provided along at least one of n parallel rail means defining the selected pathway.
The present invention relates to a rail system for a powered pallet conveyor. The rail system comprises alternative pathways for a vehicle conveying a pallet along rails. A pathway in general means a connection between a starting point of a vehicle and a destination point of the vehicle which is provided by rails.
The powered pallet conveyor vehicle may be either loaded with a pallet or not. The vehicle conveys a pallet, either loaded or empty, on a pathway of the rail system. The pallet may be conveyed along the rail system with reduced frictional resistance by the use of wheels. The wheels may be attached to the vehicle by means of a bogey or bearing system and/or to the rails, so that they function as rollers or skatewheels. The wheels additionally serve to guide the vehicle along the rails and/or effect conveyance of the pallet.
The vehicle is powered by electrical potential energy, wherein an electric motor or motors convert the potential energy into movement of the vehicle in a particular direction along an alternative pathway of the powered pallet conveyor. The motor may be attached to the vehicle, wherein all or a selection of the wheels of said vehicle are driven by said motor. However, in the case where the conveyor comprises a rail system with wheels (rollers) attached to the rails, the motors may instead be attached to the rail system and power all or a selection of the wheels of the rails.
The rail system comprises alternative pathways for a vehicle traveling along an electric cable means. The electric cable means is provided on at least one of n parallel rail means defining a travel pathway, wherein n≧2. Thus, a travel pathway is defined by two or more parallel rails, at least one of which carries an electric cable. When n=2, the travel pathway has two parallel rails, either one or both of the rails may carry an electric cable. The electric cable means is a cable capable of carrying electric current. The electric current may be used to either relay information or provide energy for powering the conveyor.
Thus, the electric cable comprises an electrically conductive wire, either in the form of a solid wire or woven strands. The electrically conductive wire comprises a metal selected from the list including copper, aluminum, gold and silver, either singly or in combination. The wire may be jacketed in an electrically insulative material such as polyethylene or polyvinylchloride. Further jacketing with mineral insulation, fiberglass armor, helical steel tape, aluminum armor, lead armor, woven bronze wire or woven steel wire may be employed to protect the cable. Alternatively, multiple wires, each optionally insulated, may be housed in the electrically insulative jacket.
The rails of the rail system comprise fixed (non-moveable) portions of rail, as well as the rigid rail portions of the first and second actuating means that may be selectively positioned so as to bridge the fixed portions of rail. The fixed portions of rail may be defined as those rails which are not rigid rail portions of the first or second actuating means. Selective positioning of the rigid rail portions of the first and second actuating means so as to comprise n parallel rail means defining a travel pathway, results in the rails of the rail system comprising a means for conveying and guiding the vehicle on a pathway of the rail system. The rails may additionally comprise at least part of the means for driving the vehicle, such as the rack of a rack and pinion. The rails may, furthermore, comprise a means for conducting electricity, such as an electrically conductive “third rail” system for electrifying the rail system.
Material suitable for the construction of the rails includes metals, alloys and polymers, used singly or in combination. The rails may comprise any of the metals selected from iron, copper, aluminum, tin, zinc, titanium, lead, manganese, chromium, vanadium and tungsten, either singly or in combination. In a further embodiment, the rails may comprise any of the alloys selected from steel, brass, bronze, Hastelloy, Electrum, Cupronickel and Duralumin. Optionally, the rails may comprise a polymer such as polyethylene, polystyrene, nylon and teflon, either singly or in combination. Particular combinations of these materials as composites, laminates, impregnates or coated materials may be used to provide rails with specific properties. For example, the rails may comprise a hybrid material such as steel laminated with aluminum which is not only capable of withstanding the stresses involved in conveying and guiding a vehicle along alternative pathways, but also is highly conductive. Alternatively, the rails may comprise iron or steel that is coated or laminated with a teflon so as to reduce friction and wear. Alternatively, the rails may comprise an electrically conductive material such as brass or a metal coated polymer, so as to themselves form an electric cable means along the travel pathway.
Each rail may have a profile which is a particular shape in cross section. In a preferred embodiment, the cross section may be an I- (or H-) shape, a T-shape, an L-shape, a U-shape or a rectangular shape. Variations on these profiles, such as the asymmetrical I-beam, flat-bottomed, bullhead, single parallel, parallel, grooved rail, flanged rail or bridge rail profiles may be employed, either singly or in combination. Most preferred is the embodiment in which the rail is an I-shape in cross section.
The rail means defining a travel pathway comprises parallel rails. Parallel rails are rails which are equidistant from one another (wherein the minimum distance between rails is essentially the same at any given position along the length of said rails). The rail system of the present invention comprises at least two alternative travel pathways each comprising at least two such parallel rail means subject to switching. Each rail means is comprised of at least two fixed sections, optionally joined to at least one moveable section (rigid rail portion) attached to an actuating means of the rail system.
Specifically, the rail system is characterized by a switch means. The switch means (a rail switch or rail points) is for switching between m alternative travel pathways, wherein m≧2. When m=2, the rail system allows for the powered pallet to be conveyed along one of two alternative travel pathways downstream from a given position along the travel pathway subject to switching. Similarly, when m=3 or greater, one of three or more alternative travel pathways downstream of a given position along the travel pathway may be selected.
In a preferred embodiment, the rail system of the present invention may comprise a means for determining the position of a vehicle and communicating the position to a control means. Indeed, selection of a particular travel pathway and control of the rail system may be achieved manually or automatically. In the case where the rail system is controlled automatically, a programmable logic controller (PLC) may be used. The PLC electronically controls how individual sections of the rail system interact with the vehicle, and, hence, pallet, being conveyed. In particular, the PLC controls the positioning of the first and second actuating means in relation to the vehicle. Furthermore, the PLC controls the movement and positioning of the vehicle in relation to the rail system. The PLC is able to convey a vehicle through multiple rail systems of the invention. Moreover, the PLC is also able to convey multiple vehicles through either an individual rail system or multiple rail systems of the invention.
Electronic control of how individual sections of the rail system interact with the vehicle may be achieved by the use of rails which are capable of carrying electric current. The movement of the vehicle may also induce electric current. The electric current may be relayed along the rail and thereby provide information as to the location of the vehicle on the pathway. Alternatively, the rail may carry current for driving the actuating means and/or powering the vehicle.
Selection of a particular travel pathway is made prior to the vehicle reaching the alternative pathways. Specifically, the switch means for switching between m alternative travel pathways, wherein m≧2, allows the vehicle to continuously move across the switch after switching. Accordingly, a travel pathway allowing the vehicle to continuously travel across the switch on at least one of n parallel rail means defining the travel pathway is provided in advance of said vehicle reaching said switch. With switching made downstream of the vehicle, the vehicle need neither stop nor slow down for selection to take place.
In comparison, conventional switch processes such as that of the quadro switch or rotation switch of the prior art (
Furthermore, switch processes such as that of the quadro switch or rotation switch have the disadvantage that the forces involved in the acceleration/deceleration process lead to wear on the vehicle and rail means. Additionally, the forces involved in switching whilst the vehicle is stationary on the switch similarly may lead to increased wear on the switch mechanism. The present invention overcomes such disadvantages by dispensing with the need for stopping and starting the vehicle and by effecting the switching and, thus, provision of a travel pathway in advance of the vehicle reaching said switch. Accordingly, the lifetime of not only the rail system, but also the vehicle and rail means, as well as the associated means of driving the rail system and vehicle, is increased. This leads to a reduction in the costs and time associated with maintenance of the rail system.
Switch processes such as that of the quadro switch or rotation switch have considerable space requirements, particularly when it is intended for multiple pathways to be provided. Whilst the quadro switch would appear to be an exception in this regard, this system can only comprise travel pathways that intersect each other at a fixed angle, typically 90 degrees. In order to minimize the number of switch processes for a given travel pathway made, for example, of right-angle intersections, extended lengths of rail and hence increased amounts of space must be used. The space requirements associated with a rotation switch are less considerable, but an increase in the number of alternative travel pathways provided must, necessarily, be associated with an increase in the circumference, and hence diameter, of the rotatable turntable. In contrast, the rail system of the present invention is relatively compact and is capable of providing multiple travel pathways in a confined space.
This is achieved by said switch means comprising (a) a first actuating means and (b) a second actuating means. The first actuating means and second actuating means may be operated simultaneously or at different times. Furthermore, the first actuating means and second actuating means may be operated independently or non-independently of one another. In a preferred embodiment, the first actuating means is a shifting frame. In a further preferred embodiment, the second actuating means is a shifting frame. A shifting frame is a moveable framework upon which the rigid rail portions of the actuating means are firmly attached. The shifting frame may be shifted to align different sets of the rigid rail portions of the actuating means with fixed portions of the rail in order to allow the vehicle to travel across the actuating means.
The switch comprises a first actuating means for selectively positioning (m*n) rigid rail portions bridging the distance between rail ends optionally holding cable ends at
(i) n joining points, and
(ii) (m*n) continuation points.
The n joining points are where the n parallel rail means of each of the m alternative travel pathways subject to switching converge. The (m*n) continuation points are where each alternative pathway subject to switching diverges downstream from the joining points. Thus, the first actuating means selectively positions a subset of n of the (m*n) rigid rail portions of the first actuating means between the n joining points and a subset of n of the n continuation points, so as to link the fixed portions of rail with the rigid rail portions, thereby allowing the vehicle to travel across the first actuating means.
The switch additionally comprises a second actuating means for selectively positioning [m(n−1)] rigid rail portions bridging the distance between rail ends optionally holding cable ends at crossing portions where each alternative pathway subject to switching is discontinued downstream from the corresponding continuation points. Thus, the second actuating means selectively positions a subset of (n−1) of the [m(n−1)] rigid rail portions of the second actuating means between a subset of 2(n−1) of the rail ends at the crossing portions, so as to link the fixed portions of rail with the rigid rail portions, thereby allowing the vehicle to travel across the second actuating means.
The spatial relationship between the joining points, continuation points and crossing points is described as follows. The joining points are defined by the locations where the m alternative travel paths subject to switching coincide or diverge. The continuation points are located downstream from the joining points along the selected travel path. Specifically, the continuation points are located on the first actuating means at positions distant from the n joining points along each of the alternative travel pathways subject to switching. Furthermore, the crossing points are located at positions distant from the rigid rail portions of the first actuating means along each of the alternative travel pathways subject to switching. Thus, the positioning of a set of n rigid rail portions by the first actuating means and the positioning of (n−1) rigid rail portions by the second actuating means provides a travel pathway allowing the vehicle to continuously travel across the switch along the electric cable means provided on at least one of n parallel rail means defining the travel pathway.
The rail system of the present invention may be supported by a system of sleepers or cross ties, or mounted directly on the floor, on an elevated base, overhead or any of a combination of these. In a preferred embodiment, the pathways are mounted on the floor.
The rail system may comprise horizontal pathways, inclined pathways and/or vertical pathways. In the case where pathways deviate from the horizontal, it may be necessary to use a means for driving the vehicle, such as a rack and pinion, which can overcome the issues associated with operation on gradients.
A specific embodiment of the rail system of the present invention is shown in
A plan projection of the specific embodiment shown in
An orthographic projection of the specific embodiment of
The present invention also provides a process for operating a switch of a rail system for a powered pallet conveyor according to the invention. The process comprises the steps of
(a) selecting one of n alternative pathways;
(b) positioning n rigid rail portions for bridging the distance between
(i) n joining points where the m alternative travel paths subject to switching coincide, and
(ii) n continuation points of the selected travel path downstream from the joining points,
(c) positioning n−1 rigid rail portions for bridging the distance between rail ends optionally holding cable ends at crossing portions where each alternative pathway subject to switching is discontinued downstream from the corresponding continuation points.
Each step in the process of operating a switch of a rail system for a powered pallet conveyor may be performed either manually by a human controller and/or automatically by an automated controller such as a PLC, respectively. Each step in the process may be timed to coincide with the steps of many other identical processes in order to maximize the overall efficiency with respect to time or cost of conveying multiple pallets along a pathway comprised of multiple travel pathways. An example of such a pathway is that of a powered pallet conveyor used in sorting and distributing pallets in, for example, line shaft production. Accordingly, the rail system of the present invention is suitable for use in the automobile, food, agricultural, pharmaceutical, electronic, chemical or print industries.
Selecting one of n alternative pathways is performed prior to the vehicle traveling across the switch, depending on the direction in which the pallet, and hence vehicle, need be conveyed. Selection of a pathway may be made by the controller depending on, for example, the type of load which the vehicle and/or pallet is carrying.
Subsequent to selecting one of n alternative pathways the controller establishes whether the rail system is set up such that a vehicle can cross the switch and travel along the chosen pathway. In the event that the vehicle can cross the switch and travel along the selected pathway, repositioning of the rail system is unnecessary and the rail system remains unchanged. In the event that the rail system is set up such that a vehicle cannot cross the switch and, therefore, is unable to travel along the selected pathway, repositioning of the rigid rail portions of either or both of the first and second actuating means is required. The repositioning of the rigid rail portions of the first actuating means may be performed independently of the repositioning of the rigid rail portions of the second actuating means.
Repositioning of the rigid rail portions of the first actuating means is effected by the controller sending an electronic signal to the mechanism driving the actuating means. The mechanism repositions the first actuating means so as to ensure that a subset of n of the (m*n) rigid rail portions bridge the distance between n joining points and a subset of n of the (m*n) continuation points which are located on the parallel rail means of the selected travel pathway. This allows the vehicle to subsequently cross the switch and travel along the selected pathway.
Repositioning of the rigid rail portions of the second actuating means is effected by the controller sending an electronic signal to the mechanism driving the actuating means. The mechanism repositions the first actuating means so as to ensure that a subset of (n−1) of the [m(n−1)] rigid rail portions bridge the distance between the rail ends optionally holding cable ends at a subset of 2(n−1) of the rail ends at the crossing portions and thereby allow the vehicle to cross the switch and travel along the selected pathway.
The spatial relationship between the joining points, continuation points and crossing points is described as follows. The joining points are defined by the locations where the m alternative travel paths subject to switching coincide or diverge. The continuation points are located downstream from the joining points along the selected travel path. Specifically, the continuation points are located on the first actuating means at positions distant from the n joining points along each of the alternative travel pathways subject to switching. Furthermore, the crossing points are located at positions distant from the rigid rail portions of the first actuating means along each of the alternative travel pathways subject to switching.
The process for operating the switch of the rail system thereby provides the selected pathway allowing the vehicle to travel along an electric cable means provided along at least one of n parallel rail means defining the selected pathway.
Although specific embodiments of the invention are disclosed, variations thereof may occur to an artisan, and the scope of the invention should only be limited by the scope of the appended claims.
Number | Date | Country | Kind |
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08012241.9 | Jul 2008 | EP | regional |
This application is a continuation-in-part and thus claims the benefit of and priority to U.S. patent application Ser. No. 12/495,761, filed Jun. 30, 2009 which claimed the benefit of and priority to European Patent Application No. EP 08 012 241.9, filed Jul. 7, 2008, the contents of which are incorporated by reference herein in its entirety.
Number | Date | Country | |
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Parent | 12495761 | Jun 2009 | US |
Child | 13529436 | US |