The present application claims priority to Italian Patent Application No. BO2013A000415 filed Jul. 31, 2013, the contents of which are expressly incorporated herein by reference.
Not Applicable.
The present invention is classified under international classes H01R and G09F, and relates to an electrified rail, in particularly for metal shelving units which have to be provided, on the side facing the public of the shelves supporting goods, with electronic labels, displays and/or other peripherals. Moreover the present invention relates to the method for producing such electrified rail.
As prior art, the following documents are cited.
Patent application WO 1994/22125 titled “Information display rail system” describes an extruded rail with a C-profile, to be fixed on the front side of the shelves. The rail is provided with a longitudinal top ridge into which an electrically insulating base carrying longitudinally fixed powered wires, opportunely distanced from each other. The wires are fixed with adhesive to said base for about 180° of their section, and protrude downwardly with the remaining free end, with which the spring-loaded ends of an electronic label designed to be fixed into said rail can be brought into contact.
U.S. Pat. No. 5,348,485 titled “Electronic price display system with vertical rail”, also published in 1994, describes a system to connect, through electric wires and plugs, electrified rails positioned on the front of goods-displaying shelves, on which electronic labels are fixed, with a vertical electrified rail, fixed on the uprights of the same shelving unit. The rail is made of an extruded bar inside which electrically conducting metal strips are fixed, with the interposition of an electrically insulating base, the metal strip being fixed through adhesive. The exposed surface of metal strip is touched by flexible spring-loaded electric contacts of end plugs of said connecting wires, said plugs being fixed on said vertical rail, whose electric conductor are connected with their top end to means positioned on the top part of the shelving unit, the means providing supply and control of said electronic labels.
French patent FR 2 765 018 titled “Systeme d'etiquette electronique d'affichage” filed in 1997, describes an electrified rail made of an extruded plastic bar, having a C-profile, on whose bottom is fixed for all its extension an electrically insulating base, on which metal strips are longitudinally fixed through adhesive. Said metal strips are connected with one end to supply and/or control means, while the rail is profiled so as to fix an electronic label having on its rear spring-loaded contacts touching said metal strips, to realize the necessary connection of electronic label with remote supply and control means.
GB patent 1273670 (A) describes a current supply bar comprising an elongate metal support connected by lugs to a wall or ceiling, a flexible strip of insulating material held in the support by flanges, and metal conductors. The strip is provided with grooves into which the conductors are laid when it is flat but which retain the conductors when the strip is bent about its longitudinal axis. The strip is also provided with cavities and/or elevations between the conductors.
U.S. Pat. No. 2,234,745 (A) describes an electric connecting device comprising a rail formed from flexible dielectric material, like for instance rubber. It is provided with a base having flanges whereby the device may be secured in position. Extending through the device and opening at the top edge thereof are two interspaced grooves separated by a centrally arranged ridge. The spacing of the grooves and therefore the width of the ridge is such that the grooves will receive the prongs of a connector. Outer walls are provided on the rail and in the inner face of each of these walls is formed a semi-circular groove in each of which is mounted one of the bus bars made from flexible wire coiled in the form of a helix. When assembling the bus bars in the rail, the bars may be slipped endwise into the grooves while separating the walls slightly so as to allow the bars to be forced down into the grooves until they come opposite the semi-circular grooves, whereupon they will snap into position and will resiliently held in place.
The prior art and all the state of the art known in this technical field have the following limitations:
Referring to the electric conductors of all rails, be they in the form of wires or strips, the part of their surface which is not fixed to support insulating material is visible and easily reachable by a person's fingers, with ensuing safety problems, both for the persons and the electronic labels, whose contacts may be damaged by electrostatic shocks deriving from accidental contacts.
Another disadvantage of the known state of the art is the poor reliability in the fixing of electric conductors to supporting rail through adhesives, whose features tend to modify over time, due to the heating electric conductors undergo because of Joule effect. To remedy this problem, the teaching of U.S. Pat. No. 5,890,918 may be used, which describes how to realize an electrified rail using an extruded body of hard material, also electrically conducing, providing said body with a longitudinal slot with a circular section, outwardly open with a part lower than 180° of its section. In said slot a copper wire is inserted through pressure, the wire being insulated through a sheath of plastic material, having an external diameter equal to the diameter of said slot, so that the same wire can be pressure-inserted and can remain friction-trapped in said slot, which surrounds it for more than 180° of its electrically insulating external sheath. This solution entails the use of pointed pins on plugs and peripherals; the point must be able to pierce wire insulation and to touch the same copper wire to establish the needed electrical contact. This solution entails also very high contact resistances, due to the limited surface contact between pointed pins and conductor wire. Insulation piercing technique needs a strong force to allow the contact point to pierce wire insulation and to touch the wire itself, deforming it to ensure an efficient contact. In U.S. Pat. No. 5,890,918 said force is obtained through a screwable contact in a corresponding seat of the electrified rail. If we consider that every contact must have its own electric insulation and a robust threaded body to ensure a resistant screwing in the electric rail seat, e.g. three or four electric conductors, it is easy to understand that miniaturising the electrified rails and the relative contact plugs becomes very difficult, according to U.S. Pat. No. 5,890,918. Other disadvantages come from the fact that screwable plugs can be subjected to loosening caused by vibrations, with diagnostic and maintenance difficulties. Further disadvantages derive from the fact that every time the peripheral is moved on the electrified rail, other tracts of wire must be pierced, while the previously pierced areas remain exposed, with ensuing problems of electric insulation and oxidation. The same U.S. Pat. No. 5,890,918 patent, as an alternative to the above illustrated solution, teaches to realize the rail with an electrically insulating material, with longitudinal slots with circular section, opened toward the exterior with a part lower than 180° of their section, and inserting into every slot an insulation-free copper wire, having an external diameter equal to that of each slot, so that the wire can be pressure-inserted into the slot, taking advantage of the elasticity of the plastics forming the rail, so that the wire is pressure-trapped in the slot, which surrounds the wire for more than 180° of its section. This solution, if on one hand tries to fix electric wires to the slots of the electrically insulating rail without using adhesives, in reality tackles the problem deriving from the difficulty of keeping the wire in the slot, due to the limited undercut with whom the slot itself holds the wire, which is necessary in order to easily overcome the undercut in the step of insertion of said electric wire into relative slot through thrust. Due to the elasticity of the plastics forming the rail, if the rail is realised with a limited section, small movements of flexion and torsion of the rail itself lead to the wires inevitably coming out from the respective slots. This embodiment, too, is an obstacle for the miniaturisation of an electric rail having a plurality of conductors, and has the above-illustrated problems on the use of plugs with screwable contacts. For these reasons, this solution is hardly feasible at the industrial level, to provide tracts of electrified rail having a length of some meters, already incorporating electric wires in the plastic bar. This solution has the same disadvantages quoted above for document WO 1994/22125, in that the electric wires protrude from their relative support slot for an ample tract of their section, and for this reason can lead to accidental short circuits.
EP Patent 1 233 482 describes the realisation of an electrified bar for use at 220-230 V. In this case, too, the bar is provided with a metal body ensuring mechanical resistance, thermal resistance and linearity; in opposed and flanked positions, longitudinal slots are obtained, the slots being capable of containing plastics extrusions having in their turn deep and narrow longitudinal slots with intermediate, longitudinal and flanked recesses, capable of holding respective electric wires which in this way are sufficiently backed in the respective slots and protected against accidental contacts. This solution does not solve the problem of the miniaturisation of the electrified rail, and does not teach how to realise an electrified rail with a plurality of conductors placed side by side, with an industrial extrusion method, capable of providing bars having a limited section, the desired length and ready to use.
Finally, WO patent 9516293 (A1) describes a conductor rail comprising a bearing structure, an insulator and a conductor or conductors, according to which the bearing structure and the insulating structure of the conductor rail are produced as the same uniform structure by the extrusion method and the conductors are inserted in the rail after extrusion, which allows the bending of the rail under heating or without heating, in any direction, before the insertion of the conductors or after insertion. The conductor rail may be formed from PVC, ABS, Polypropylene, Polyethylene or Polycarbonate, or acrylic resins. No mention is made in this document from the feature that the rail can be flexed fanwise transversally before the insertion of the conductors.
All the known electrified rail use an electrically insulating PVC or similar plastic body, which offer a poor safety in terms of electric insulation, which sometimes are not self-extinguishing, and have poor capacity to resist overheating, which can develop for possible failures or overload. Moreover, they have poor resistance to mechanical deformation, already at temperatures near to 100° C. In the known electrified rails, electric wires are inserted into the plastic body after its formation, taking advantage of the deformability and of the elasticity at the relatively cold temperature of the plastics itself. In order to assume the necessary linear form of mechanical resistance, to the electrically insulating plastic body of known type an external support and rigid body is paired, generally made of metal, with further manufacturing problems and with deducible difficulties in realizing electrified rails having a limited section.
For supplying electronic labels and/or other peripherals to be fixed on metal shelving units produced by the applicant, the applicant could not find on the market an electrified rail, and had therefore to design an electrified rail having the following features:
The electrified rail must be in the form of a monolithic body of extrudable plastic material, having good features of rigidity and mechanical load, similar to those of metal, in order to have a section of limited width, a linear form and to directly support the peripherals; at the same time, it must have a good electric insulation, to directly support a plurality of naked electric wires, ensuring a good reciprocal insulation of the single wires, and outwardly; finally, it must have good fire resistance and self-extinguishing capacity, and a good capacity of resisting to mechanical deformation, even when exposed to temperature around 100° C. To this aim, the rail is preferably made of polycarbonate (PC), commercially known e.g. under Makrolon® or Lexan® brand, or in polyphenylene oxide (PPO), commercially known e.g. under Noryl® brand, or equivalent materials;
The rail must have a body with a profile capable of being fixed on a support surface; to any point of the rail electric connection plugs, electric devices or other accessories must be removably fixed; its longitudinal outward surface must be planar and provided with a plurality of slots; in each slot an electric wire is contained, having a portion of its section outwardly open, so that such part of wire can be reached by the spring-loaded pins for electric contact with plugs or devices which can be fixed on the rail itself;
The rail must be produced in tracts having a pre-defined length, e.g. two meters long, with the wires are already tightly held, and must be realised on an industrial scale with a repeatable method, a method easily integrable with the known extrusion methods for plastic material. The technical problem to be solved in the manufacturing through extrusion of a rail body with the plastic material quoted above consists in the insertion of the electric wires into the extruded rail, in that the usual technique for pressure-inserting wires into the structurally defined profile at room temperature cannot be used, as it would lead to the breakage of the profile itself and/or to inacceptable deformation of the electric wires. The present invention solved this technical problem through a particular profile of the rail body, and inserting into it the electric wires after the extrusion step. In particular, the insertion is performed during the calibration step, when the profile is still hot. In this step, the profiled and extruded rail undergoes a transversal flexion which brings the slots surrounding the electric wires to outwardly diverge and open, so as to easily insert the respective electric wires, with a continuous method. The electric wires are preferably heated to a temperature preventing thermal shock in the contact with the extruded plastic material into which they have to be inserted. Afterwards, always during the sizing step, the profiled rail is brought back to its original intended profile, so that its slots close and tightly hold the electric wires, with an undercut having a width sufficient to hinder the accidental successive loss of said wires. To check the transversal opening of the rail and to avoid the formation of unwanted stretch, a suitable profile of the slots containing the wires and of other parts of the rail itself was designed;
Electric wires must not protrude from the containing slots with a portion of their section, but they must be reachable by the electric contacts of the peripherals, only through channels having a limited width and a sufficient depth, so that immediate and accidental contacts with said wires are prevented;
The electric wires must be externally nickel- or gold-plated, and the electric spring-loaded contacts of the pins of plugs and peripherals must be plated in the same way, so as to ensure a high resistance to oxidation and a low electric contact resistance;
The rail must have limited dimensions, e.g. a width of about 20 mm, and a reduced thickness, so as to have a low aesthetic impacts, both for the formation of horizontal electrified rail, to be applied on the front end of shelves, and of vertical electrified rails, to be applied on shelving unit uprights. The vertical rail connects said horizontal rails, through wires and relative plugs, to remote supply and control means of electronic labels and/or other peripherals fixed on the same horizontal electrified rails;
The rail must have lateral and/or anterior profiles such as to allow the fixing to the rail itself of any suitable peripheral, independently from the number of conductors (two or four);
The rail must have rear and/or lateral profiles such as to render its fixing flexible to a support which can be e.g. the upright, a shelf or the back, or interposed parts, of a shelving unit.
Other features of the invention, and the advantages it procures, will be made clearer by the following description of certain preferred embodiments of said invention, illustrated purely by way of non-restrictive example in the figures of the accompanying four sheets of drawings, in which:
With reference to
On the bottom of each slot 3 small longitudinal, middle grooves 6 can be opened, wide and deep about 0.5 mm and useful for what will be explained later. The base 101 of the rail is completed by longitudinal lateral, external grooves 7 and 8, at least one for each side. These lateral grooves have preferably different profiles and dimensions, to increase the possibility of installing rail 1, and/or to pair to it external components, and also to facilitate proper orientation of the rail itself, in relation to the different intended use of the internal electric wires 4. A part of said wires can be destined to supply electric power, preferably low voltage, while the other wires can be kept as a reserve or can be used to transmit data (see in the following) or to other uses. Purely by way of non-restrictive example, the lateral groove 7 has a width F of about 0.8 mm and a substantially rectangular profile, while the groove 8 has bigger dimensions than groove 7, and a perpendicular V-profile.
On the bottom side 2 of base 101, small groove or cuts 9 may open, useful for what will be explained later, having equal or different dimensions from those of foundation grooves 6, with respect to which the same grooves 9 have a symmetrical and offset position.
Always referring to
The thickness H of rail body 1 is about 7-8 mm and the thickness M of the various areas forming the wings and the base of the rail itself was kept constant as much as possible and near to the value of 1.6 mm, so as to uniform the shrinkage of the material of rail 1, to avoid deformation, and to ensure its production with a rectilinear shape. The depth P of channel 10 is about 3.45 mm, while the overall width N of the electrified rail 1 is about 19-20 mm.
According to the embodiment of
The above-cited plastic material (PC, PPO) used for making the rail body 1 or 100, can be used to be extruded with a final transparent or translucent features, and therefore to manufacture a rail with a further limited aesthetic impact and suitable for the application to shelves of any colour. The grey of the nickel-plating or gold of gold-plating of electric wires 4 will contribute to ensure a pleasant aesthetic pairing of the rail itself to shelves of any colour.
The manufacturing method of the above-described electrified rail through extrusion comprises the following steps:
feeding the extruder with a suitable plastic material (e.g. PC or PPO), and extruding the profile;
the extruded profile passes to a calibration station;
in the calibration station the extruded profile is paired to copper wires. To avoid the formation of unwanted tensions in the rail formed in the calibration unit, and to confer a sufficient plasticity to wires 4, before inserting them in the calibration station, the same electric wires 4 are heated to a temperature near to that of the extruded plastic forming the rail body; usually this temperature is kept between 60 and 100° C.
the extrusion-wires pair is longitudinally pulled and cooled;
the extrusion-wires pair is cut in tracts of suitable length.
During the cutting step pressing and counter-pressing means are used, to hold electric wires 4 in their respective slots. This occurs in an understandable and easily feasible way for a skilled person.
During the calibration step, the extruded plastic profile 101, 201, 301, 401 undergoes a transversal bending as shown in
From
It is apparent from
In
In
Always in
Thanks to the particular configuration of the rail, according to which all wires are lying on the same flat in-sight surface 102, in combination with a spring loaded contact pin having a preferably rounded point, it is achieved that the plug can slide longitudinally along the axis of the rail without losing the electric contact and without leaving damage grooves on the wires. This feature is obtained in combination with the use of nickel-plated or gold-plated contact surfaces, which prevent the formation of oxides and which render unnecessary the mechanical penetration of the metals.
It is understood that to the present invention numerous variants and modification can be introduced, without for this departing from the underlying principle of the invention as described, illustrated and claimed in the following.
In the claims, the reference numbers shown in brackets are purely indicative and do not limit the scope of protection of the claims.
Number | Date | Country | Kind |
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BO2013A000415 | Jul 2013 | BO | national |
Number | Name | Date | Kind |
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4121879 | Olsen | Oct 1978 | A |
4812134 | Miller | Mar 1989 | A |
4976633 | Beghelli | Dec 1990 | A |
5348485 | Briechle | Sep 1994 | A |
5485933 | Crooymans | Jan 1996 | A |
7122744 | Walter | Oct 2006 | B2 |
7425140 | Lehman | Sep 2008 | B2 |
8286768 | Schmiedle | Oct 2012 | B2 |
8968011 | Hoffmeister | Mar 2015 | B2 |
20080166006 | Hankey | Jul 2008 | A1 |
Number | Date | Country | |
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20150037991 A1 | Feb 2015 | US |