BE1027721B1 - Spacer, electric fence holder connectable with a spacer and fence comprising spacer - Google Patents

Abstract

The disclosure relates to a spacer for spacing an electric fence from a carrier, the spacer comprising an electric fence end and a carrier end. The spacer according to the disclosure is characterized in that it is elastically deformable under load. The disclosure also relates to an electric fence holder that can be coupled to spacers in accordance with disclosure and to a fence comprising a spacer in accordance with disclosure.

Description

Spacer, electric fence holder connectable with a spacer and fence comprising spacer

[1] The disclosure relates to a spacer for spacing an electric fence from a support, the spacer comprising an electric fence end and a support end. The disclosure also relates to an electric fence holder that can be coupled to spacers in accordance with the disclosure, in particular in the event that such an electric fence holder is not an integral component of the spacer, and to a fence comprising a spacer in accordance with the disclosure, as well as at least one carrier. and electric fence.

[2] Spacers for keeping an electric fence at a distance from a carrier are, for example, known in agriculture. Spacers are often used here for holding an electric fence to demarcate an area in order to keep animals inside or outside the area. The known spacers should be marketed as cheaply as possible because large numbers of spacers are quickly required for a fencing of a field. Such known spacers are therefore usually made from cheap material, such as plastic, also because of its insulating properties, so that a voltage on an electric fence wire is kept at a suitable distance from a support, such as a fence post. However, such known spacers break easily under load as usually occurs in agricultural conditions, such as a weight or force of animals on the spacers or even a pulling or pushing force of those animals on the electric fence, agricultural machines and any attached tools. Particularly with commonly used large weights of these animals or agricultural machines, spacers can be exposed to large loads.

[3] Spacers as known from the prior art have the problem that they break under load, even if this is a normal load for the circumstances. Furthermore, weather conditions often have adverse effects on the load capacity of spacers. For example, it is known that spacers can withstand less load at low temperatures and thus break faster.

[4] It is an object of the disclosure to provide spacers that reduce or remedy the above problems.

[5] This object is achieved by a spacer for keeping an electric fence at a distance from a carrier, wherein the spacer comprises an electric fence end and a carrier end and wherein the spacer is elastically deformable under load. To this end, the spacer is manufactured from an elastically deformable plastic.

[6] Because the spacer is elastically deformable under load according to the disclosure, at least part of the load is applied to elastically deforming the spacer. This reduces the chance of the spacer breaking under the load. The spacer thus absorbs the load without breaking, or at least breaks it only with a greater force than rigid or lightweight spacers known from the prior art. Above all, the invention goes against the notion that the spacers must necessarily be manufactured from as cheap and as little material as possible, whereby any additional cost but longer life of spacers according to the present disclosure amply outweighs breakage and replacement of known spacers.

[7] In the context of this disclosure, electric fence is also understood to mean variants of electric fence, such as a single or multiple lines, wherein the lines can be formed from wires, cables and/or ribbons. This includes electric fence tape, scare tape, metal cables and barbed wire.

[8] Preferably, the elastic deformability of the spacer is at least equal to a lower limit sufficient to withstand a load-causing force without fracture. Because the spacer has an elastic deformability that is equal to or greater than said lower limit, the spacer does not break under the load causing force.

[9] A load causing force is preferably related to the weight of an animal or agricultural machine. The term animal here includes humans and, for example, poultry, cattle and vermin, the purpose of which is to keep them inside or outside a plot by means of the electric fence. Agricultural machinery includes human-driven vehicles, such as tractors, harvesters and their trailers, as well as self-propelled vehicles, such as automatic tractors or combine harvesters. Other load-causing forces may also be relevant in the application conditions of spacers, such as load associated with mounting the spacer on the carrier, the application of the electric fence wire and forces exerted on the spacer via the electric fence wire.

[10] Preferably, the spacer is elastically deformable with respect to a longitudinal direction corresponding to the distance, which deformation comprises at least one of: - twisting, - bending, - stretching, and - contracting.

[11] Twisting is particularly favorable with an upward or downward movement of the electric fence, which results in an upward or downward load on the spacer. Bending is particularly favorable with an inward or outward movement of the electric fence resulting in an upward or downward loading of the spacer, and with a direct loading of the spacer. In addition, stretching and contracting alone or in combination with twisting and/or bending are beneficial in many cases.

[12] Preferably, the spacer between the electric fence end and the carrier end comprises a profile from a group comprising: - an I-profile, - a H-profile, - a U-profile, and - a tube profile.

[13] The choice of a profile is partly dictated by a desired deformability of the spacer. Advantages of said profiles include that an I-, H- or U-profile has a deformability that differs according to a direction of the load with respect to the profile. In an I-profile, for example, the height of the upright relative to the width of the two beams determines the deformability of the I-profile as a result of a load applied transversely to the I-profile. The deformability here is therefore direction dependent. In the case of the tube profile, on the other hand, the deformability as a result of a load applied transversely to the profile is the same in all transverse directions.

[14] Preferably, the spacer is made of a material made from a group comprising: - natural rubbers, - synthetic rubbers, - elastomers, and - silicones.

[15] Said materials have the advantage that they are intrinsically elastically deformable. As a result, the spacer can be manufactured from one element and very diverse functional shapes and manufacturing methods, such as injection molding, can be selected. The spacer can be designed to be elastically deformable such that it can withstand load without breaking, specifically for a desired application.

[16] Said materials also have the advantage that they are intrinsically electrically insulating, so that the electric fence wire is insulated from the carrier and a voltage applied to the electric fence wire during use does not leak away via the spacer.

[17] Furthermore, a spacer manufactured from said materials has the advantage that it remains elastically deformable under various weather conditions. As a result, it does not break faster in changing weather conditions, such as a decrease in temperature.

[18] Preferably, the spacer comprises at least one of nylon and MDI. MDI stands for methylenediphenyl diisocyanate.

[19] It is particularly advantageous if nylon and MDI are used together, because such a material remains elastically deformable even in cold conditions as it does not become brittle and thus breaks less quickly. This material also has the advantage that it can be designed such that it is selectively deformable. For example, in case the spacer comprises the I-profile, it allows twisting to a greater extent under load than bending distortion.

[20] Preferably, the electric fence end spacer is provided with an electric fence holder configured to hold the electric fence. The electric fence can consist of one or more variants, as mentioned above, wherein the electric fence holder can be configured to hold one or more of said variants simultaneously or separately. For example, the electric fence holder may be configured to hold a ribbon and/or a wire. The electric fence holder can also be integrated with the electric fence and/or the spacer.

[21] Preferably, the electric fence holder comprises a snap closure with a base and a pivoting arm. When closing the snap closure of the electric fence holder, the arm moves towards the base and the arm engages in the base, whereby the arm and base undergo an elastic deformation and then relax and interlock. Due to the click closure, the electric fence can be releasably connected to the spacer via the electric fence holder. This facilitates installation and makes it possible to replace individual spacers, even with existing fences, so that they can be used as a retrofit.

[22] Preferably, the base includes an anvil and the arm includes a hammer. When such an electric fence holder is closed, the hammer comes into contact with the anvil, causing a vibration. This is caused, for example, by the elastic deformation and relaxation of the arm and base. In a favorable embodiment, the vibration is perceptible to a person, in particular by touch or by ear. As a result, the vibration can form a signal to confirm closure of the electric fence holder.

[23] Preferably, the base further comprises a reinforcement to promote a vibration corresponding to closure of the electric fence holder. By promoting the vibration by means of the reinforcement, the vibration is preferably perceptible in agricultural situations, such as outdoors, in wind and weather, near working agricultural machinery, near running engines, near animals that make noise and in situations where a combination of the the foregoing factors - or even all factors at the same time - contribute to making it more difficult to detect closure of the electric fence holder.

[24] It is of great importance that the closure of the electric fence holder can also be observed under such situations in order to be sure that the electric fence wire is correctly connected to the spacers and the fence formed with it is intact. Errors during assembly, which can lead to animal suffering or economic damage, are thereby prevented or at least reduced.

[25] The above problem is particularly relevant when using elastic materials, as suggested above for various embodiments of a spacer according to the disclosure. In the case of elastic material, any vibration that may be present for fastening the closure is less perceptible. After all, elastic material has an inherent damping of vibrations. By arranging the reinforcement in the base of the electric fence holder in accordance with disclosure, vibrations are obtained upon closing the electric fence holder which are clearly perceptible to touch or hearing, even in the agricultural situations outlined above.

[26] In addition, the reinforcement also serves to secure the closure, which can be advantageous with clastic materials. After all, elastic material can plastically deform over time, so that the electric fence holder closes less tightly. This is prevented or at least reduced by applying the reinforcement in accordance with disclosure.

[27] Preferably, the electric fence holder is releasably connected to the spacer. This allows the electric fence holder to be replaced individually without disassembling or detaching the spacer.

[28] Preferably, the spacer is provided at the carrier end with a carrier holder configured for holding the spacer to the carrier. The carrier can comprise one or more variants, such as a round, square, rectangular or octagonal post, a fence, a mesh, a net and one or more cables, bands or wires. The carrier holder can also be integrated with the carrier and/or the spacer.

[29] Preferably, the carrier holder is releasably connected to the spacer. This allows the carrier holder to be replaced individually without disassembling or detaching the spacer. The spacer can herein also be replaced with a carrier holder connected to the carrier, without the carrier holder having to be detached from the carrier.

[30] The disclosure also relates to an electric fence holder that can be coupled to a spacer in accordance with the disclosure. The electric fence holder can be designed in accordance with disclosure according to at least one of the embodiments described above. The electric fence holder thus has the advantages mentioned therein.

[31] The disclosure also relates to a fence comprising a spacer according to the disclosure, a support and an electric fence. The spacer can thereby be designed in accordance with disclosure according to at least one of the embodiments described above. This means that the fence has the advantages mentioned. The support and the electric fence of the fence can be provided in at least the variants described above.

[32] The disclosure is further explained with reference to the following figures.

[33] FIG. 1 schematically shows a spacer according to an embodiment of the disclosure in perspective.

[34] FIG. 2 schematically shows an electric fence holder according to an embodiment of the disclosure in side view.

[35] FIG. 3 schematically shows a fence according to an embodiment of the disclosure in perspective.

[36] In the figures and the accompanying description that follows, elements are designated with the following reference numerals: 1 distance, 2 electric fence, 3 support, 4 fence, 100 spacer, 110 profile, 120 electric fence end, 130 girder end, 200 electric fence holder, 210 base, 211 anvil, 212 gusset, 220 arm, 221 hammer, 230 holes, 300 carrier holder, 310 joint, X first transverse, Y second transverse, and Z longitudinal.

[37] In FIG. 1 shows a spacer 100 for keeping an electric fence 2 at a distance from a carrier 3 . The spacer 100 comprises an electric fence end 120 and a carrier end 130 having at the electric fence end 120 an electric fence holder 200, which is manufactured integrally with the spacer 100, and having at the carrier end 130 a carrier holder 300, which is releasable to the spacer 100 via a connection 310. connected.

[38] The spacer 100 is elastically deformable under load.

[39] The elastic deformability of the spacer 100 may be at least equal to a lower limit sufficient to withstand a load causing force without fracture.

[40] The deformability may depend on the direction of the load. Three directions are shown to further elucidate this dependence: a first transverse direction X, a second transverse direction Y and a longitudinal direction Z corresponding to the distance 1. In this example the three directions are mutually perpendicular to each other, but this is not the case in all embodiments. necessarily the case.

[41] The spacer 100 may be elastically deformable with respect to a longitudinal direction Z corresponding to the distance 1, which deformation includes at least one of twisting, bending, stretching, and contracting. In this example, twisting is a rotation about the longitudinal direction Z, bending is a curvature in the first transverse direction X and/or the second transverse direction Y, stretching is an extension in the longitudinal direction Z and contraction is a shortening in the longitudinal direction Z. Combined deformations are also possible, for example twisting and contracting at the same time.

[42] The spacer 100 comprises a profile 110 between the electric fence end 120 and the carrier end 130. The profile 110 can be chosen from a group comprising: an I-profile, an H-profile, a U-profile and a tube profile. In fig. 1 shows an I-profile by way of example. The cross section of the I-profile contains an upright with a height along the second transverse direction Y and contains two beams with a width along the first transverse direction X. The height of the upright and the width of the beams partly determine the deformability of the I-profile and thus the deformability of a spacer 100 equipped therewith. In this example, the height of the upright is greater than the width of the beams. The deformability of the I-profile, and thus the spacer 100, is thus greater for a load along the first transverse direction X than for a load along the second transverse direction Y. Similar arguments apply for the H-profile and the U-profile. The deformability of the spacer 100 can also be determined by a suitable choice and design of the profile 10. For example, a tube profile has the property that it has the same deformability in all transverse directions X, Y. The deformability along the longitudinal direction Z can also be predetermined by design of the profile. The profile thus has a greater deformability as it is made thinner.

The spacer 100 may be made of a material from a group consisting of natural rubbers, synthetic rubbers, elastomers and silicones. Preferably, the spacer 100 comprises at least one of nylon and MDI, and more preferably both nylon and MDI.

[44] As shown in FIG. 1, the spacer 100 may be provided at the electric fence end 120 with an electric fence holder 200 configured to hold the electric fence 2.

[45] The spacer 100 may be provided at the carrier end 130 with a carrier holder 300 configured for holding the spacer to the carrier 3

100. Preferably, the carrier holder 300 is releasably connected to the spacer 100, for example by means of the connection 310. In FIG. 1, the connection 310 is shown as a bolt, which releasably fastens the carrier holder 300 to the spacer 100 with a nut (not shown) and bore holes (not shown). Furthermore, in FIG. 1 shows the carrier holder 300 round, which makes it suitable for, for example, a round post. Other shapes and configurations are possible, such as a rectangular shape or a configuration where the carrier holder 300 is angled relative to the spacer 100.

[46] In FIG. 2 shows an electric fence holder 200 according to an embodiment of the disclosure. In this embodiment, the electric fence holder 200 is, as in FIG. 1, integrated with the spacer 100 manufactured.

[47] The electric fence holder 200 can be provided with openings 230 which are configured for guiding or clamping the electric fence wire 2, in this example also the electric fence wire 2 being understood to mean one or a combination of the above-mentioned variants. The openings 230 may include a slot, a recess and a hole. For example, a slot is favorable for an electric fence, a recess is for example favorable for a cable and a hole is favorable for a wire, for example.

The electric fence holder 200 may include a snap closure with a base 210 and a pivotable arm 220 . The openings 230 can herein be formed - at least partially - between or through the base 210 and the arm 220. After closing such an electric fence holder 200, the electric fence 2 can be clamped between the base 210 and the arm 220. In other cases it may be desirable to only guide the electric fence 2 so that the electric fence 2 can slide through the electric fence holder 200 without clamping it. Because the electric fence holder is manufactured integrated with the spacer, the electric fence holder is also manufactured from the same clastic material. This allows the swing arm to rotate relative to the base in a more optimal manner. More specifically, by using this material between the base and the swivel arm, no fold line will become visible and no break will occur.

[49] Preferably, the base 210 comprises an anvil 211 and the arm 220 a hammer

221. The anvil 211 and the hammer 221 cause a vibration when the electric fence holder 200 is closed. Furthermore, the base 210 may comprise a reinforcement 212 to promote said vibration.

The electric fence holder 200 may be releasably connected to the spacer 100, for example by a connection similar to the connection 310 of the carrier holder 300 to the spacer 100.

[51] The electric fence holder 200 can be manufactured as a separate product and can be designed to be coupled with a spacer 100.

[52] In FIG. 3 shows a fence 4, which comprises spacers 100, carriers 3 and one electric fence 2 . The carriers 3 are shown here as piles which are arranged transversely on or in a ground. However, the carriers 3 can also be arranged at an angle to said bottom or parallel to said bottom.

[53] The fence 4 may comprise a plurality of spacers 100, a plurality of carriers 3 and/or a plurality of electric fence wires 2. These multiples are not necessarily equal, so it is possible that several spacers 100 are arranged per carrier 3, which hold several electric fence wires 2 .

[54] In the above examples, the spacer 100 has been described mainly as a separate element according to the disclosure. However, it is also possible within the scope of the disclosure to manufacture the spacer 100 integrated with the electric fence holder 200 and/or the carrier holder 300 . It is also possible to manufacture one or more than one spacer 100 integrated with the carrier 2. This can facilitate and speed up the erection of a fence 4 .

[55] The spacer 100 can be manufactured by means of injection molding. This partly depends on the choice of material. Other manufacturing methods such as cutting, milling, extrusion and cold forming are also possible. It is thus apparent that many additional and alternative embodiments are possible within the scope of the present disclosure, which is therefore not limited to the specific embodiment(s) shown and described, but only by the appended claims, in particular the independent conclusions. For example, in certain embodiments, an electric fence holder may be missing at the electric fence end of the spacer and be provided loose to mate with the spacer at the electric fence end thereof. In another embodiment it is possible that the electric fence holder is an integral part of the spacer. Again, these are only examples.

Claims (14)

Conclusions 1. Spacer (100) for keeping an electric fence (2) at a distance (1) from a carrier (3), wherein the spacer (100) comprises an electric fence end (120) and a carrier end (130), with characterized in that the spacer (100) is made of an elastically deformable plastic. wherein the spacer (100) comprises a material from a group comprising: - natural rubbers, - synthetic rubbers, - elastomers, and - silicones. The spacer (100) according to claim 1, wherein the elastic deformability of the spacer (100) is at least equal to a lower limit sufficient to withstand a load causing force without fracture. Spacer (100) according to claim 1 or 2, wherein the spacer (100) is elastically deformable with respect to a longitudinal direction (Z) corresponding to the distance (1), which deformation comprises at least one of: - twisting, - bending , - stretch, and - contract. 4. Spacer (100) according to any of the preceding claims, wherein the spacer (100) between the electric fence (120) and the carrier end (130) comprises a profile (110) from a group comprising: - an I-profile, - an H-profile, - a U-profile, and - a tube profile. A spacer (100) according to any preceding claim, wherein the spacer (100) comprises at least one of nylon and MDI. A spacer (100) according to any one of the preceding claims, which is provided at the electric fence end (120) with an electric fence holder (200) configured for holding the electric fence (2). The spacer (100) of claim 6, wherein the electric fence holder (200) comprises a snap closure having a base (210) and a pivotable arm (220). The spacer (100) of claim 7, wherein the base (210) comprises an anvil (211) and the arm (220) comprises a hammer (221). The spacer (100) of claim 8, wherein the base (210) further comprises a stiffener (212) to promote a vibration corresponding to closure of the electric fence holder (200). A spacer (100) according to any one of claims 6 to 9, wherein the electric fence holder (200) is releasably connected to the spacer (100). A spacer (100) according to any one of the preceding claims, which is provided at the carrier end (130) with a carrier holder (300) configured for holding the spacer (100) to the carrier (3). The spacer (100) according to claim 11, wherein the carrier holder (300) is releasably connected to the spacer (100) 1s. An electric fence holder (200) connectable to a spacer (100) according to any one of claims 6 to 10. Fence (4), comprising a spacer (100) according to any one of claims 1 to 12, a support (3) and an electric fence (2).