NL1013707C2 - Optic fiber guide and deflector has an elastic material with a high friction coefficient in contact with the optic fiber for a secure grip without damage - Google Patents

Abstract

The guide (1) or deflector for optic fibers has an elastic material at least where it is in contact with the optic fiber, and which has a high friction coefficient. The elastic material is a natural or synthetic rubber. The guide (1) has a cylinder body (2) with an end flange (3).

Description

Title: Device for guiding and reversing light waveguides.

The invention relates to a device for guiding or reversing light waveguides, which device serves for guiding, reversing and also reversing light waveguides in connections of light waveguides (splits -5 cassettes, shunt dividers, sleeves and the like) for supplying and discharging light waveguides to connection locations, such as split-in units and coupling plates and the like. Such devices for guiding and reversing light waveguides aim to ensure that no lower diffraction radius is used than the minimum diffraction radius that is permitted for the glass fibers used in light waveguides. The usual devices for guiding or reversing light waveguides, therefore, prevent glass fibers in light waveguides from being bent to below a guiding path critical to those glass fibers and / or determining prescribed paths.

Conventionally, such devices for guiding or reversing light waveguides are made of plastic and / or metal and have a smooth and hard surface.

A disadvantage with these known devices for guiding and reversing is that the light waveguides easily slip on it, which already leads to considerable problems when the light waveguides are placed.

In the context of this description, the term "light waveguide" includes not only light waveguide cables as such, but also parts of light waveguide cables and light waveguides, as used in shunt dividers, cable sleeves and the like. Therefore, the term "light waveguide" in this description also includes so-called "pigtails" and the embodiments thereof, viz. The new page 2 ft light waveguides with a plug at one end, wherein the light waveguide may be a protective tube. in the case of thin-walled protective tubes that receive the glass fibers serving as a light waveguide, this is referred to as "fiber-pigtails." When the protective tube of a "fiber-pigtail" is surrounded by yarns in another, thicker walled wall for strain relief purposes a protective tube, the so-called "cable pigtails" are referred to. A subset of "pigtails" are the so-called "patch cords", which are light waveguides with plugs at both ends, insofar as the light waveguide is incorporated in a thin tube. referred to as “fiber patch cord.” If the light waveguide of a patch cord is incorporated in a thicker protective tube, it is also referred to as "cable patch cords". Finally, the term "light waveguide" in this description also includes so-called bundle cores, which are understood to mean a number of glass fibers serving as light waveguide in a protective tube which are intertwined in the light waveguide cable. The plugs on "pigtails" or on "patchcords" are connected to each other by couplings, these couplings generally being mounted on a plate, which is called shunting plate or coupling plate. Such shunting plates or coupling plates are also referred to as so-called "patch panels".

The measures in the preamble of independent claims 1, 19 and 21 are known from the Swiss patent CH 686 694.

The solution according to the above-mentioned publications CH686694A relates to a guide for the light waveguide in the form of guide grooves in two essentially parallel and spaced apart intermediate walls, between which an elastically deformable material is arranged with a material that is higher than the light waveguide coefficient of friction. The light waveguide is thereby pressed into the elastically deformable material with a lid-shaped downholder.

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However, the disadvantage of this is that the light waveguide rests against the relatively sharp edges of the guide groove and can thereby be damaged. In the known solution, there is also a separation between the conduction of the light waveguide and the strain relief provided therefor, which is provided by pressing into the elastic material.

The invention has for its object to provide a solution in which conduction and strain relief of the light waveguide occur and whereby the disadvantages occurring in the known solution such as, for example, the abutment of the light waveguide on sharp edges in the region of the guidance or the inversion occur where appropriate. , is avoided.

The stated object is achieved with a device for guiding or reversing light waveguides with the features of claim 1.

Preferred embodiments and advantageous embodiments are subject of the subclaims.

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Because the device according to the invention for guiding or reversing light waveguides does not consist, as is known, of smooth plastic material or metal, but of an elastic material, for example of an elastic rubber-like material such as for instance an artificial rubber such as EPDM or a natural rubber, and the material with respect to the light waveguides has a large surface frictional resistance, the advantage is obtained that a special friction is created by the special surface with tensile forces exerted on the light waveguides 10 and that without special measures a strain relief is provided, for example with split-in sliding units and coupling plates is achieved.

According to the invention it is not required that the entire device for guiding or reversing light waveguides consists of an elastic rubber-like material, but it is sufficient that those parts of the device against which the light waveguides abut are made of an elastic material which of the light waveguides exhibits a large coefficient of friction, for example from an artificial rubber such as EPDM or natural rubber.

The device according to the invention for reversing or guiding light waveguides can be hollow, for example honeycomb-shaped, so that in the case of a tensile load on the light waveguide abutting or guided by the device (surface) distortion occurs. As a result, the radius of curvature of the light waveguide is increased and pulse-shaped tensile loads are damped, which advantageously leads to few losses occurring in the line.

As noted, the parts for guiding or reversing need not consist entirely of an elastic material. It is sufficient if (only) the surface or part of the surface that serves for guiding or reversing is (rubbery) elastic but with a correspondingly large coefficient of friction.

The device according to the invention can also be shaped such that the light waveguide is completely or partially enclosed, so that the device can serve not only as a guide, but also as a strain relief due to the high friction.

The device according to the invention for guiding or reversing light waveguides can be provided with means which prevent the light waveguides from sliding off thereof. Such members can be rigidly connected to the device for guiding or reversing light waveguides. They can, however, also be detachable or foldable with respect to such guides or reversals.

The invention is elucidated on the basis of the following description of preferred embodiments, with reference to the drawings, in which: Fig. 1 shows a device for reversing light waveguides obliquely seen from below, Fig. 2 a device for reversing a semicircular design of Fig. 3 shows a device for guiding light waveguides, Fig. 4 shows a device for guiding light waveguides, Fig. 5 shows a funnel-shaped device for guiding light waveguides, Fig. 6 a represents a device for reversing light waveguides similar to the device according to fig. 1 provided with an outer protective wall, fig. 7 shows another embodiment of a device 35 for reversing light waveguides, fig. 8 yet another embodiment of a device for guiding lich 8 shows waveguides, and FIG. 9 is a sectional view of the device 5 of FIG.

The device 1 for reversing light waveguides shown in Fig. 1 consists of a cylinder 2, the lateral surface of which forms the reversing surface and of a flange 3 projecting at the upper end of the cylinder 2, which slide off the light waveguide from the device 1. This flange 3 can be connected to the cylinder 2 in one piece or (detachably, for example by means of a clamp or pressure connection) attached to the cylinder 2. The flange 3 can also be wholly or partially foldable.

Fig. 1 shows that the device 1 is hollow, in particular honeycomb-shaped through intermediate walls 7, so that the cylinder 2 of the device 1 can deform when pulled on the light waveguide, which is at least partially guided around the device 1, so that the radius of curvature of the light waveguide is increased.

The device 1 shown in Fig. 1 need not consist entirely of rubbery elastic material, which material has an increased coefficient of friction relative to the relevant light waveguides. It is already sufficient if at least the outer surface 4 of the cylinder 2, which forms the main part of the device 1 according to Fig. 1, consists wholly or partly of a rubbery elastic material with an increased coefficient of friction.

The embodiment of the device 1 shown in Fig. 2 differs essentially from the embodiment shown in Fig. 1 in that the part 5 serving for the actual reversal has a semicircular cross-section. It is also shown in Fig. 2 that the part 5 forming the device 1 can be hollow 6. For the rest, the explanations for the embodiment of the device 1 shown in Fig. 1 also apply to the device 1 according to Fig. 2.

FIG. 3 shows an embodiment of the device 15 in which the part 6, which inverts the light waveguide and is at least partially wound by it, has a kidney-shaped cross-section. For the rest, the explanations for the devices 1 shown in Figs. 1 and 2 also apply to the embodiment of the device 1 according to Fig. 3.

Fig. 4 shows an embodiment of a guide 9 for light waveguides, in particular for pigtails. In the embodiment shown, the guide legs 10 have an arcuate design at least on one or both side surfaces of rubber-like elastic material, with a large coefficient of friction relative to the light waveguide and are provided with ribs 12 and grooves 11 on the faces facing each other, so that the Light waveguides, for example pigtails, received in the gaps 13 between the guide legs 10 are partially enclosed, so that, in addition to a guide, a strain relief and attachment of the light waveguides is achieved.

In the embodiment shown in Fig. 4, the guide legs 10 may consist of a rubber-like elastic material which has an increased coefficient of friction relative to the light waveguides. There is the option of manufacturing the entire guide 9 of Fig. 4 from an elastic rubber-like material.

However, the device 9 according to Fig. 4 can also be embodied such that only the guide legs 10 consist of rubbery elastic material with a coefficient of friction which is increased relative to the light waveguides, these guide legs being attached to a base part 14 of any material, for example from metal or plastic.

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Finally, it is also possible to form the guide legs 10 in such a way that caps made of a rubber-like elastic material with a coefficient of friction increased relative to the light waveguides are slid as enclosures on tongues rising upwards from the base part 14.

It is also important in the case of a device for guiding, for example the device 9 of the embodiment shown in Fig. 4, that the parts of the device 9 which come into contact with the light guides to be guided thereby consist of the rubber-like elastic material with an increased coefficient of friction relative to the light waveguides.

The guide 20 shown in Fig. 5 serves to pass light waveguides through walls in splitter carriers, splice cassettes or dividers. Here too it is worthwhile if the guide 20 is made of rubbery elastic material with an increased coefficient of friction with respect to the light waveguides, in particular tubes or pigtails. The guide 20 can be made entirely of rubbery elastic material, which has the further advantage that the device can be secured in corresponding penetrations of components, through which the light waveguides have to be passed, by clamping or pressing therein under elastic deformation.

The embodiment of a device 1 for reversing a light waveguide shown in Fig. 6 corresponds to that of Fig. 1, wherein in the embodiment shown in Fig. 6 the device 1 is surrounded by an outer (protective) wall 8, wherein the outer wall 8 is substantially semi-circular in curvature. The cylinder of the actual reversal 1 is then arranged eccentrically with respect to the outer (protective) wall 8, so that a wider input 21 and a narrower output 22 for light waveguides is obtained. The free edge of the wall 8 remote from the base 8 can be provided with a flange 23. The embodiment of a reversing device 1 shown in Fig. 6 can include the outer (protective) wall 8 in one piece from rubbery elastic material are manufactured. As has been described for the other embodiments of reversing device 1 and guiding devices 9 and 20, it is also possible with the embodiment shown in Fig. 6 to use only the parts of the reversing device 1 which come into contact with the light waveguides, therefore essentially the outer surface of forming the cylinder 2 and the inner surface of the wall 8 of rubbery elastic material with an increased coefficient of friction relative to the light waveguides. FIG. 7 shows a reversing device 1 similar to that of FIG. 1, which can be axially compressed with the aid of a screw 24, so that the lateral surface 4 of the cylinder 2 of the reversing device 1 is turned outwards and the light waveguides, for example pigtails, against rigid guides 25 extending from a support 30 disposed under the cylinder 2. The friction is thereby increased and an even more efficient strain relief is created. The embodiment shown in Fig. 7 represents a combination of a guide, an inversion and a strain relief. The screw 24 can be screwed into a plate, wall or the like, of a shunting distributor or the like. In certain cases, the screw 24 may also be screwed into the carrier 30 of the guides 25.

FIG. 8 shows a feed-through which can be used, for example, in a feed-through screw coupling (PG screw coupling). FIG. 9 shows the lead-through of FIG. 8 in section. The cap-shaped closures 26 of the feed-through channels 27 can be cut off as required, whereby the required cylindrical feed-through channels 27 are opened. A "pigtail" can now be inserted through this opening. The cylindrical opening can also be cut open radially 9 to the outside in order to be able to insert "patch cords" (with two plugs). The elastic part is deformed by pressure on the circular surfaces 28 and 29, so that the cylindrical inner wall of the feed-through channels 27 turns inward and creates an increased friction for the light wave conductor, for example the pigtail. The feed-through further comprises an elastic, essentially cone-shaped extension piece 31, which prevents the feed-through pigtails or patch cords from being kinked and thus damaged. This conical extension 31 may contain additional guides according to the inventions, which are connected to the extension 31 in one piece or can be mounted on it.

New to the bushing according to Figs. 8 and 9 is that this bushing consists of elastic material and forms a strain relief therefor due to the high coefficient of friction with the light waveguides, in connection with the attachment 31 which prevents bending of the light waveguides below the critical radius of curvature and that the cylindrical feed-through channels 27 are closed and first opened as required.

Claims (29)

1. An inversion for providing a guideway for a light waveguide, wherein the inversion is at least partly made of an elastic material with a coefficient of friction higher than the light waveguide and partly abuts the light waveguide, characterized in that at least a part of the inversion that provides the guideway of the light waveguide, abuts the light waveguide and consists of an elastically deformable material. 2. An inversion according to claim 1, characterized in that the device consists entirely of a rubbery elastic material with a large coefficient of friction relative to the light waveguides. 3. An inversion according to claim 1, characterized in that the device consists of a preferably rigid basic body which is provided at least on the parts which come into contact with the light waveguides with a coating of a rubbery elastic material with relative to the light waveguides 15 large coefficient of friction. 4. An inversion according to any one of claims 1-3, characterized in that the material is a natural rubber. 5. An inversion according to any one of claims 1-3, characterized in that the material is a synthetic rubber, in particular EPDM. 6. An inversion according to any one of claims 1-5, characterized in that the inversion (1) consists of a cylinder (2) and, where appropriate, a flange (3) arranged at the end thereof. An inversion according to claim 6, characterized in that the cylinder (2) has a circular cross-section. An inversion according to claim 6, characterized in that the cylinder (2) has a semi-circular cross-section. 1013707 · 11 An inversion according to claim 6, characterized in that the cylinder (2) has a kidney-shaped cross section. An inversion according to any one of claims 6-9, characterized in that the cylinder (2) is hollow. 10 New conclusions An inversion according to claim 10, characterized in that a core and of these intermediate walls (7) leading radially to the wall of the cylinder (1) are provided in the cylinder (2). 12. An inversion according to any one of claims 1-11, characterized in that a curved wall (8) is provided radially outside the cylinder (2) of the inversion (1). An inversion according to claim 12, characterized in that the wall (8) and the cylinder (2) are arranged eccentrically with respect to each other. An inversion according to claim 12 or 13, characterized in that the cylinder (2) and the wall (8) start from a common base. An inversion according to any one of claims 12-14, characterized in that the wall (8) is provided on its edge with a flange (23). An inversion according to any one of claims 1 to 11, characterized in that at least one guide (25) is provided at a distance from the outer surface (4) of the cylinder (1) which is preferably rigid and / or to the outer surface ( 4) is coaxially curved. The inversion according to claim 16, characterized in that the cylinder (2) is axially compressible. 18. Reversal according to claim 17, characterized in that a member, in particular a screw (24), is provided in the cylinder (2) for axial compression. 19. Guide (9) for light waveguides, wherein at least a part of the guide contacting the light waveguide is made of an elastic material with a higher coefficient of friction relative to the light waveguide, the guide (9) having a plurality of guide legs (10) comprises gaps (13) for receiving light waveguides, characterized in that the guide legs (10) are made on at least one slit-defining side wall of an elastically deformable material, the mutually facing sides of the guide legs (10) include ribs (12) and grooves (11). Guide according to claim 19, characterized in that the guide tracks (10) are curved. 21. Guidance for light waveguides, wherein at least a part of the lining of an elastic material coming into contact with the light waveguide is provided with a higher coefficient of friction relative to the light waveguide, wherein the lining (9) is arranged in a basic body, preferably arranged in parallel. liner channels (21), characterized in that the liner channels (27) run in the elastically deformable material and are closed at one end by a separable closure (26). 22. Guide as claimed in claim 21, characterized in that the basic body is essentially rotationally symmetrical and comprises an annular surface (38) at a distance from its basic surface (29). Guide as claimed in claim 21 or 22, characterized in that an extension piece (31) is provided in addition to the feed-through channels (27). 24. Guide as claimed in claim 23, characterized in that the feed-through channels (27) are arranged around the extension piece (31) coaxial with the axis of the basic body. Guide as claimed in claim 25 or 26, characterized in that the extension (31) is essentially cone-shaped. 26. Guide as claimed in any of the claims 19-25, characterized in that the device consists entirely of a rubber-like elastic material with a large coefficient of friction relative to the light waveguides. 27. Guide as claimed in any of the claims 19-25, characterized in that the device consists of a preferably rigid basic body which is provided at least on the parts coming into contact with the light waveguides with a coating of a rubbery elastic material with a large coefficient of friction relative to the light waveguides. A guide as claimed in claim 26 or 27, characterized in that the material is a natural rubber. A guide according to any one of claims 26-28, characterized in that the material is a synthetic rubber, in particular EPDM.