WO2007026096A1 - Linear element for an electric fence - Google Patents

Abstract

The invention relates to a linear element for an electric fence, comprising at least one electrical conductor which is built into at least one plastic support. The inventive linear element also comprises at least one textile yarn which is totally or partially built into the support, said conductor and said textile yarn forming a structural unit with the support. The aforementioned support is fully or partially made from a semiconducting plastic material. According to the invention, the support defines repellent areas at which an electrical contact can occur with any body or element external to said structural unit.

Description

LINEAR ELEMENT FOR ELECTRIC FENCE

FIELD OF THE INVENTION

The present invention relates to the protection of property, in particular the protection of agricultural property, for example for the parking of animals or the protection of crops.

To confine farm animals to a limited surface area, or to discourage animals from approaching crops or property that they may damage, it is known to delineate the land where the animals are found. breeding or the property to be protected by an electric fence.

PRIOR STATE OF THE ART

An electric fence necessarily comprises the following three elements: an electrification system, which transforms the input electric current that can have an AC voltage of 110 V or 230 V or a DC voltage of 9 to 12 V into an output current at high voltage pulses, for example from 10,000 to 12,000 V, of sufficient amperage, but of very short duration. This electrification system can be powered by any means suitable for the ground to be delimited, for example an electric accumulator or the electrical network. a linear and conductive element which drives the electric current generated by the electrification system on the perimeter of the fence and which therefore transmits this current to the animals that come to touch it. This wire may be a simple wire, but it is generally preferred a linear element composed of metal son and plastic son, such as cord, rope or ribbon, to obtain a better mechanical strength and a better visibility of the electric fence . insulators that hold these linear elements in place and also provide electrical insulation of the electric fence with respect to the earth.

Electric fences are of very different lengths. In fact, long or very long fences require effective electrification over their entire length to repel animals by electric shock all around the enclosed grounds. For a fence to provide a so-called repulsive function, it must be sufficiently electrified for an animal that comes into electrical contact with these areas to move away from it as a result of the electric shock then received, thereby inducing instinctive repulsion. This animal will be "repulsed" away from the linear element, either in the enclosure or outside, depending on the purpose of the electric fence. For this, the linear element must transmit pulses of selected voltage depending on the animals to be repelled and for example of the order of 2,500 V for a cow, 1,500 V for a horse and between 3,000 and 4,000 V for a sheep.

In addition, fences must also be made of sufficiently strong and properly assembled wires to withstand external mechanical stresses. Indeed, if a rupture of the linear element occurs, the continuity of the electrical conduction may be affected, so that the fence no longer ensures its repulsive function.

The linear element must therefore be chosen to ensure cumulatively the breaking strength and electrical conductivity of the fence, adapted to the animal species to park or to move away. The breaking strength and the electrical conductivity respectively depend on the physical properties of the plastics yarns, essentially thermoplastic, and the electric conductive yarns used, in addition to their numbers, families, diameters and methods of assembly.

There are commercially available linear electric fence elements made from a process used in the textile industry, which will be detailed below.

Depending on the method of assembling the wires together to manufacture the linear elements, there are three types of linear elements: ribbons: flat linear elements of width generally between 5 and

50 mm thick and generally between 0.8 and 3 mm. The ribbons are made by weaving or even knitting for the largest ribbons; cords: linear elements of substantially circular section of diameter generally between 1.5 and 3 mm. The cords are made by twisting - joining or braiding; the ropes: linear elements of substantially circular section of diameter generally between 3 and 12 mm. The ropes are made by twisting - assembling or braiding. A ribbon, a cord and a rope are therefore formed on the one hand of plastic threads, the diameter of which is generally between 0.2 and 0.5 mm, and on the other hand of conductive threads, generally of metal , whose diameter may be between 0.15 and 0.5 mm. Such a cord is for example described in FR-A-2702876.

The drawbacks inherent in such a linear element lie in the fact that the manufacturing processes implemented prove to be expensive, and that the resulting products also have the technical weaknesses described below, which may limit the use thereof to electric fences.

Indeed, all the previously described manufacturing processes, resulting from the textile industry, comprise in particular the following operations: extrusion of thermoplastic yarns, winding of thermoplastic yarns, introduction of thermoplastic yarn coils and reels of electrical conductor wires on a creel, to feed either a loom for making a ribbon or a twister - joiner to make cords or ropes; in the latter case, the bobbins of threads are either placed on a creel or placed inside the twister.

In addition, for braiding, the threads are wound on small cans which are then placed on a braider.

These operations require many manipulations, frequent changes of coils and therefore specialized personnel. Consequently, the risks of manufacturing errors and therefore of poor workmanship of the linear elements are not negligible; these risks therefore generate significant quality control costs. These methods of manufacturing linear elements for electric fence therefore produce linear elements relatively expensive.

In addition, the technical characteristics of the linear elements thus produced can limit their use for an electric fence. Thus, the majority of the products currently on the market do not meet the real needs of the users, that is to say a linear element having conductors with good electrical conductivity in order to ensure the desired repulsive function of the fence and sufficient mechanical strength. Indeed, their heterogeneous assembly causes the main technical weaknesses described below.

To compensate for the relatively high cost of producing these linear elements, in particular due to the labor required, the diameter of the conductors is limited in order to reduce the quantity of raw material. On the one hand, this affects the electrification of the fence, because their electrical resistance increases with the decrease of their cross section, and on the other hand, it decreases their mechanical resistance.

Indeed, in a linear element obtained by a heterogeneous assembly of metal and thermoplastic son, it is often the metal son, having an elongation at break much lower than that of the thermoplastic son, which break first. The break can occur when the conductors are subjected to excessive mechanical stress, as may be the case during the various phases of unrolling and rewinding the fence during the tensioning thereof on site. The rupture can also be consecutive to the corrosion of the oxidizable metal wires or to the local burning of the plastic parts.

Corrosion is generally due to the effects of moisture, for example in the form of salt spray, or atmospheric pollutants, such as exhaust fumes or residues from spray products. It is possible to use stainless steel to avoid corrosion, but as soon as the fence has to extend over a certain length, it is necessary to use a wire of good conductivity, usually copper or even aluminum. Copper, whether tin-plated, nickel-plated or silver-plated, is likely to oxidize, sometimes even very rapidly.

The burns are caused by the vegetation coming into contact with the linear element or by the nodes of connections that the user makes with the fence wire and which locally increase the electrical resistance of the metal parts, therefore the temperature of the linear element .

Thus, a linear element whose conductive wire is corroded or whose plastic son are burned has reduced mechanical strength. Therefore, the life and / or efficiency of the electric fence are reduced. For an electric fence to provide its repulsive function, it must therefore include a sufficiently solid linear element, electrical conductor and, if possible, a reasonable manufacturing cost.

SUMMARY OF THE INVENTION

The present invention provides a positive response to the various technical and economic disadvantages mentioned above.

The object of the invention is therefore to propose a linear element whose mechanical, electrical and economic characteristics make it possible to obtain an effective electric fence at an affordable cost. This linear element is obtained by a homogeneous and not heterogeneous assembly of the metallic and plastic materials that compose it.

The present invention relates to a linear element for electric fence comprising at least one fully integrated electrical conductor inside at least one plastic support. According to the invention, this linear element further comprises at least one textile yarn wholly or partially integrated within said support, said conductor and said textile yarn forming a structural unit with said support, said support consisting entirely or partly of semiconductor plastic material. Thus, according to the invention, this support defines repulsive zones at which electrical contact with any body or element external to said structural unit is likely to occur.

In other words, one or more conductors and at least one textile thread are embedded in a plastic carrier conducting electricity and able to repel animals.

Thus, the electrical conductor no longer has an exposed surface, which prevents any subsequent oxidation of the conductor, and the textile thread provides good resistance to mechanical stresses that may be experienced by the structural unit constituting the linear element, and this, despite possible burns of the plastic support.

In addition, such a linear element can be obtained by an inexpensive manufacturing process because excluding braiding and / or twisting - assembling steps. To ensure good mechanical strength, especially in tension, the textile yarn may be a continuous yarn or not, twisted or not, composed of several filaments, a braided from the trade, a monofilament or horsehair that will be sized and arranged to conferring on the structural unit a resistance to the mechanical (and / or thermal) stresses it is likely to undergo.

Advantageously, the electrical conductor may extend generally over the entire length of the support and have a length at least equal to that of the support.

Thus, the conductivity of the structural unit is ensured by the same conductor over the entire length of the linear element. In other words, the conductor conducts the current continuously all along the linear element. This makes it possible to minimize the electrical resistance of the linear element, thus the electric losses by Joule effect.

According to one embodiment of the invention, the support can be made of several plastics belonging to the same family, which can simplify its production and facilitate control of the mechanical characteristics of the linear element. Thus, it may be envisaged to make part of the polyvinyl chloride (PVC) support loaded with carbon black.

The same family comprises polymers composed from similar monomers, but with different addition elements. A family can for example include all the grades of polyethylenes and polypropylenes.

However, the support can also be made of several plastics of different families.

According to an economic embodiment of the invention, the support may comprise a part made of insulating plastic and low cost. Nevertheless, the semiconductor portion of the support extends over the entire length of the structural unit.

Thus, the electrification is ensured at any point around the fence but the insertion of insulating plastic can reduce the cost of the raw material and contribute to the good mechanical strength of the fence. According to an advantageous form of the invention, the support may comprise a plastic material loaded with reinforcing fibers, such as glass fibers. Thus, the linear element has improved mechanical strength, especially in tension and in flexion - compression.

According to a particular form of the invention, the linear element may be in the form of a ribbon, the support having a substantially elongate section and the electrical conductor extending longitudinally with respect to the main dimension of the ribbon.

This is one of the classic forms of linear fence elements. It gives a greater visibility to the linear element, and thus optimizes its repulsiveness.

According to a preferred form of this particular embodiment of the invention, the ribbon may have through orifices formed between the electrical conductors and intended to allow the passage of fluid, including wind or rain.

According to another particular embodiment of the invention, the linear element may be in the form of a rod (cord or cord), the support having a substantially circular section and the electrical conductor extending substantially in the direction main ring.

This is another of the classic forms of linear fence elements. It provides isotropic mechanical strength to the linear element and therefore does not have a preferred shear direction.

In practice, the support can have a single color or different colors. This improves the visibility of the linear element forming the fence or facilitate recognition for commercial purposes or production and storage.

To further facilitate the recognition, the plastic material may be able to be marked with one or more intelligible inscription (s), for example alphanumeric (s) or ideographic (s).

According to a particular embodiment of the invention, the linear element may comprise a plurality of electrical conductors made of the same material or of different materials. The materials are chosen according to the electrical conductivity and the mechanical strength of the linear element desired. Thus, copper is, in known manner, better conductor than stainless steel, but may have lower mechanical properties and corrosion resistance with respect to the desired use.

In practice, the linear element may comprise several electrical conductors of identical or different cross sections. Here again, the choice will be made according to the desired use.

The invention also relates to a method of manufacturing a linear fence element according to one of the embodiments described above. According to the invention, this method comprises an extrusion step, but no step of twisting - assembly, nor braiding of the plastic support.

Thus, this method is relatively simple to implement and, therefore, inexpensive because it does not involve a complex step of shaping textile.

According to a particular form of implementation of the method - object of the invention, this method can comprise:

an extrusion step of extruding a ribbon comprising a plurality of conductive wires extending substantially parallel to one another and longitudinally inside at least one support made entirely or partially of semiconductive plastics material;

- A step after the extrusion step of cutting said ribbon into sub-strips of smaller width, each of said sub-tapes comprising at least one of said conductive son.

The linear element object of the invention reduces the importance of the aforementioned drawbacks of electric fences of the prior art. Indeed, the structural unit formed by the electrical conductor and the textile thread embedded in a semi-conductive plastic support gives it greater mechanical strength, good conductivity throughout the perimeter and allows a gain in productivity, so a reduction of the cost of production by eliminating several manufacturing steps.

It is therefore possible to propose either electric fences at a more affordable cost, or electric fences with equivalent cost that are stronger and better conductors by using conductors of larger cross section. BRIEF DESCRIPTION OF THE FIGURES

The invention will appear more clearly in the light of the following description of several particular embodiments of the invention, which refer to the figures. The object of the invention is not limited to these particular forms and other embodiments are possible.

Figure 1 is a perspective view showing a ribbon according to the invention.

Fig. 2 is a perspective view showing a ribbon according to another embodiment of the invention.

Figure 3 is a perspective view showing a rod (rope) according to the invention.

Figure 4 is a perspective view showing another embodiment of a rod (rope) according to the invention.

Figure 5 is a schematic perspective representation of an intermediate phase of making a ribbon according to an embodiment of the invention.

EMBODIMENTS OF THE INVENTION

Figure 1 shows a longitudinal fraction of a linear element for electric fence according to the invention. This linear element consists of a plastic support (2) and an electrical conductor (1), which is in the form of a wire of circular section. In addition, a textile thread (3) is twisted around the conductive thread (1).

According to the characteristic embodiment of the invention, the conductive yarn (1) and the textile yarn (3) are coextruded with the plastic support (2). They are thus totally integrated inside the support, in order to form a structural unit constituting the linear element (left part of FIG. 1). Production by coextrusion therefore does not require know-how or complex textile machines, and is therefore quite easy.

On the right part of the figure, to simplify the understanding of the invention, the support does not overmold the son (1) and (3). This may be for example an end left free for connection to a conventional electrification system as mentioned above. The plastic support (2) shown in Figure 1 is composed of a single semiconductor plastic material, here polyvinyl chloride (PVC), such as that marketed by Solvay® under the name Benvic ^® and the reference KG410900AB. It could also be polypropylene (PP) produced by LNP ^® under the name STATKON Ml HI.

Other semiconductive polymers can be used, alone or in combination, with conventional conductivity (P.C.C.) or intrinsic (P.C.C.). In general, conventional semiconductor plastics (P.C.C.) have a black-filler charge to increase their conductivity. It goes without saying that the semiconductor must be chosen according to the desired mechanical and thermal resistance for an application to an electric fence.

The electrical conductors son (1) are here made of copper, to ensure the transmission of the electric current generated by the electrification system (not shown) over the entire length of the linear element. Copper is a good conductor, but it is easily oxidizable. However, when it is implemented in accordance with the present invention, it is integrated in the plastic support (2), thus protected from corrosion by external agents.

The plastic support (2) has a single color not shown here. This color is chosen bright to improve the visibility, therefore the recognition, of the linear element forming the fence. However, another color may be considered, to facilitate recognition for commercial, production or storage purposes.

Moreover, it may be envisaged to mark the support (2) so as to enter, by etching, screen printing or any other technique, information relating to the product, the supplier or marks indicating the linear element footage already used.

In the embodiment of the invention shown in FIG. 2, the linear element is a flat ribbon, therefore of elongated cross section, which comprises two electrically conductive wires (la, Ib) parallel to each other, and extending along the plastic support (2), therefore the linear element. In this case, the two conductive son substantially define the two free longitudinal edges of said ribbon. In addition, the electrical conductor son (Ia, Ib) extend generally over the entire length of said support (2) and has a length at least equal to that of said support. In other words, the wire conducts the current continuously all along the linear element. This makes it possible to minimize the resistance of the linear element, therefore the electrical losses by Joule effect.

Furthermore, it may also be envisaged, according to a particular embodiment of the invention, to provide through holes in the zone (7) between the electrical conductors (la, Ib). These orifices are intended to allow the passage of fluid, including wind or rain.

Likewise, it may be provided, in accordance with another embodiment, to use an insulating and inexpensive plastic to form the zone (7), such as for example PVC or a conventional polypropylene, and thus reduce the costs of manufacturing by limiting the use of semiconductor plastic to the only areas surrounding the conductive wires (la, Ib).

The ring shown in Figure 3 has a single electrical conductor (5) in the form of a wire or cable (right part of the figure to simplify understanding). According to the invention, the linear element further comprises a textile thread (6) twisted around the conductive wire (5) and which gives it its strength. The wires (5) and (6) are coextruded with the semiconductor plastic support (4) so as to form a structural unit, as seen on the left side of FIG.

Here again, the electrical conductor wire (5) extends generally over the entire length of the support (4) and has a length equal to that of the support (4). It is thus able to ensure continuous electrification of the linear element.

In an even simpler way to achieve and still according to a method according to the present invention, the textile yarn (6) is not even twisted around the electrical conductor wire (5) but directly coextruded with it in the support (4), as shown in Figure 4. In doing so, further reduces manufacturing costs, and corollary it facilitates the implementation of the invention during production, and without penalizing the mechanical strength to traction. As already said, the linear element of the invention may be in the form of a ribbon, that is to say have a certain width. According to a method of embodiment of the invention, more particularly described in connection with FIG. 5, this ribbon (9) firstly results from an extrusion step of extruding a larger element, comprising several ribbons secured between them and comprising several son son (1) extending substantially parallel to each other, the plastic material of said ribbons being semiconductor.

Then, after the extrusion, it proceeds to the realization of a cut in order to individualize the ribbons (7) in question, according to the lines in broken lines (8).

Of course, these cuts are made in such a way that each of the strips thus individualized comprises at least one of said conductive wires.

The linear elements described above make it possible to limit the importance of the drawbacks identified in the prior art, that is to say that they give the electric fence better mechanical properties and better conductivity at a lower cost than the elements. linear of the prior art previously described.

Claims

Linear element for electric fence comprising at least one electrical conductor (1; la, Ib; 5) integrated inside at least one support (2; 4) made of plastic, characterized:

In that it further comprises at least one textile thread (3; 6) totally or partially integrated inside said support (2; 4), said conductor and said textile thread (3; 6) forming a structural unit with said support (2; 4),

And in that said support (2; 4) consists wholly or partly of semiconductive plastics material so as to define repulsive zones at which electrical contact with any body or element external to said electrical contact is likely to occur; structural unit.

2. linear element for electric fence according to claim 1, characterized in that the textile yarn (3; 6) is a braided yarn, dimensioned and arranged to confer on said structural unit a resistance to mechanical and / or thermal stresses that she is likely to suffer.

3. Linear element for electric fence according to one of claims 1 or 2, characterized in that the electrical conductor (1; la; Ib; 5) extends generally over the entire length of the support (2; 4) and presents a length at least equal to that of said support (2; 4).

4. Linear element for electric fence according to one of the preceding claims, characterized in that the support (2; 4) is made of one or more plastics, and, in the latter case, the same family or different families.

5. linear element for electric fence according to claim 4, characterized in that the support (2; 4) comprises a portion made of insulating plastic material (7) and low cost, the semiconductor portion of said support (2; ) nevertheless extending over the entire length of said structural unit.

6. Linear element for electric fence according to one of claims 4 or 5, characterized in that the support (2; 4) comprises a plastic material filled with reinforcing fibers, such as glass fibers.

7. Linear element for electric fence according to one of claims 4 to 6, characterized in that it is in the form of a ribbon, said support (2; 4) having a substantially elongated cross section, the electrical conductor (1) extending substantially in the main direction of the ribbon.

8. Linear element for electric fence according to claim 7, characterized in that the ribbon has through holes formed between the electrical conductors (1; la, Ib; 5) and intended to allow the passage of fluid, including the wind or rain.

9. Linear element for electric fence according to one of claims 4 to 6, characterized in that it is in the form of a rod, rope or cord, the support (4) having a substantially circular section, the driver electrical (5) extending substantially in the main direction of said rod.

10. linear element for electric fence according to one of the preceding claims, characterized in that the support (2; 4) has a single color or different colors.

11. linear element for electric fence according to one of the preceding claims, characterized in that it comprises a plurality of electrical conductors (1; la, Ib; 5) made of the same material or different materials.

12. linear element for electric fence according to one of the preceding claims, characterized in that it comprises a plurality of electrical conductors (1; la, Ib; 5) of identical or different cross sections.

13. A method of manufacturing a linear element for electric fence, characterized in that it comprises:

an extrusion step of extruding a ribbon comprising a plurality of conductive wires (1; la, Ib; 5) extending substantially parallel to each other and longitudinally inside at least one support (2; 4); formed wholly or partly of semiconductor plastic material,

- A step after the extrusion step of cutting said ribbon into sub-strips of smaller width, each of said sub-ribbons comprising at least one of said conductive son.