WO2017059948A1

WO2017059948A1 - Patch cable and identification device having such a patch cable

Info

Publication number: WO2017059948A1
Application number: PCT/EP2016/001610
Authority: WO
Inventors: Clemens Wurster; Stefan Schmidt
Original assignee: Rosenberger-Osi Gmbh & Co. Ohg
Priority date: 2015-10-08
Filing date: 2016-09-27
Publication date: 2017-04-13
Also published as: DE202015007044U1

Abstract

The invention relates to a patch cable (6) having at least one data line (8), wherein a light waveguide (12) is arranged so as to extend in parallel to at least one data line (8), at least sectionally, to which light waveguide at the ends thereof one each light coupling element (14, 16) for coupling and/or uncoupling test lights into and/or from the light waveguide (12) is assigned.

Description

Rangierkabei and identification device with such

Patch Cables

The invention relates to a jumper cable according to the preamble of claim 1 and an identification device with such a jumper cable according to claim 10. The infrastructure of large data centers is based not insignificantly on a structured wiring with cables and connecting lines, which may have both electrical lines and optical fibers. This structured cabling is used to interconnect the various operational units of a data center, as well as to connect it to external networks and, for security reasons, to redundant mirror data centers.

Structured cabling, eg according to ISO IEC 11801 and EN 50173-1, distinguishes between fixed basic cabling, which can be found, for example, in the interspaces of raised floors as well as cable ducts, and other cabling. The individual channels of the stationary cables usually end at the back in the distribution cabinets of data cabinets. A connection between two channels of fixed lines as well as the connection to the active operational units takes place with the help of so-called patch cords. The patch cords are usually well visible by the surgeon arranged on the front side of the distribution box.

In the operational area of a data center, there is a constant need to reconfigure the cabling. This is done by manually repositioning jumper cables by a surgeon. However, it is often difficult for the surgeon to quickly find and identify the two ends of patch cords to be patched. If the ends to be transposed are confused, it can cause serious damage to the operation of the data center, e.g. due to interruptions of active data transmissions.

From DE 10 2008 006 429 B4 a data cable with optoelectronic signal transmitters at each cable end section is known, wherein the optoelectronic signal transmitters are electrically conductively connected to one another via one or more lines.

The invention has for its object to provide a jumper, the two corresponding ends are fast, efficient and secure and identifiable with little effort. This object is achieved by a patch cord of the type mentioned above with the features characterized in claim 1. Advantageous embodiments of the invention are described in the further claims.

For this purpose, it is provided according to the invention in a jumper cable of the aforementioned type that an optical waveguide is at least partially parallel to the at least one data line, the at each end a light coupling element for coupling and / or decoupling test light in and / or from the optical waveguide assigned. This has the advantage that an operator with a laser light source, eg a laser pointer, can couple laser light as a test light into the optical waveguide via a first of the two light coupling elements, which then exits via the second of the two light coupling elements and is visually perceived by the surgeon without interrupting the data connection can be. Thus, the optical assignment of light entry point and light exit point, a simple assignment of the ends of a umzusteckenden jumpering cable is possible.

According to one embodiment, it is provided that at least one of the light coupling elements has a fisheye lens. In this case, a fisheye lens is understood to mean a lens that projects in a straight line straight lines that do not run through the center of the image. It usually reproduces area ratios or radial distances more faithfully than a conventional, gnomonisch (not angled) projecting wide-angle lens and has a very large angle of view of mostly 180 ° in the image diagonal, in extreme cases even up to 220 °. Such a fisheye lens may have two or more convex-concave lenses. An operator may use a laser light source, e.g. at a right angle to the extension direction of the fiber optic cable. Thus, laser light incident on the side of the optical axis of the optical waveguide can be effectively coupled into the optical waveguide without problems.

According to a further embodiment it is provided that at least one of the light coupling elements has at least one biconvex lens. The biconvex, i. Both sides outwardly curved lens, also called convergent lens, is a spherically ground lens with positive refractive power. The convex surfaces are the light entrance and the light exit surface, while the lateral surface is located between the convex surfaces. An operator may also here include a laser light source, e.g. align at a right angle to the extension direction of the optical waveguide, which in turn simplifies handling. This makes it particularly easy to couple laser light into the optical waveguide.

According to a further embodiment, it is provided that the biconvex lens has a mirrored lateral surface. The mirrored outer surface avoids unwanted light emission. According to a further embodiment, it is provided that the biconvex lens has convexly shaped light entry and exit surfaces which are hemispherical in shape. This makes it particularly easy to couple laser light from the entire half-space into the optical waveguide.

According to a further embodiment, it is provided that the light coupling element has a beam deflecting device which is arranged in Prüflichtausbreitungs- direction between one of the ends of the optical waveguide and one of the light coupling elements. Thus, laser light can be coupled out of the optical waveguide and deflected. In this way, the surgeon can couple in the laser light in a particularly simple manner and then visually perceive coupled-out laser light particularly easily. According to a further embodiment, it is provided that the beam deflecting device has a mirrored reflector. The reflector cooperates with one of the light coupling elements in order to connect and disconnect test light. Thus, the beam deflecting device may be simpler in construction since it does not at the same time also cause a light deflection of e.g. 90 ° has to effect.

According to another embodiment, it is provided that the optical waveguide is made of a plastic material. Thus, the optical waveguide may comprise polymeric optical fibers (POF, English for polymeric optical fiber or plastic optical fiber). Due to their robustness against bends and shocks and their easy assembly, polymeric optical fibers are an alternative to glass fibers, especially in short-distance data transmission. The use of polymeric optical fibers instead of glass fibers makes it possible to dispense with the splicing method frequently used to connect glass fibers and the associated high outlay.

According to a further embodiment, it is provided that the jumper cable for light coupling, light guiding and light coupling out of green laser light having a wavelength of 480 nm to 560 nm is formed. Green light is particularly easy for the surgeon to visually perceive. Furthermore, the invention includes an identification device with a laser light source and such a jumper cable.

The invention will be explained in more detail below with reference to the drawing. This shows in:

Fig. 1 shows an identification device with a laser light source and a

Patch cord according to one embodiment,

FIG. 2 shows a first exemplary embodiment of a light coupling element of the jumper cable shown in FIG. 1, and FIG

Fig. 3 shows a second embodiment of a light coupling element of the jumper cable shown in Fig. 1.

Reference is first made to FIG. 1 reference.

Shown is an identification device 2 with a laser light source 4 and a jumper cable 6.

The laser light source 4 is a hand-held device such as e.g. a laser pointer of protection class 2, and emitted in the present embodiment, laser light having a wavelength in the range of 480 nm to 560 nm.

The patch cord 6 (patch cable from engl. To patch) is a type of cable used in network technology and telecommunications. The patch cord 6 is used to connect ports of a patch panel (also called patch panel) with ports of another patch panel (this connection is called patch or routing) for connecting ports of a patch panel with a network distribution device (for example, switch, hub or router) or the connection of terminals, for example a PC with a network card, to a power outlet. The length of the jumper cable 6 is in the present embodiment in the range of about 0.3 m to 25 m.

The jumper cable 6 has at least one data line 8. The data line 8 has one or more electrical lines or an optical waveguide with one or more optical fibers.

The data line 8 terminates at both ends respectively at a plug 10 for connection to terminals such as e.g. Bushings of a patch panel.

At least in sections, an optical waveguide 12 is provided parallel to the at least one data line 8, to which at its first end a first light coupling element 14 and at its second end a second light coupling element 16 is assigned. Thus, the optical waveguide 12 does not end like the data line 8 on the plug 10, but begins at the first light coupling element 14 and ends at the second light coupling element 16. The optical waveguide 12 is made in the present embodiment of a plastic material and has one or more polymeric optical fibers , The one or more optical fibers are sheathed in the present embodiment by the electrically insulating sheath of the data line, i. cohesively connected to each other.

In the present exemplary embodiment, the two light coupling elements 14, 16 each have a beam deflection device 30 for deflecting laser light (shown only in relation to the first light coupling element 14 in FIG. 1). For this purpose, in the present exemplary embodiment, the respective light coupling element 14, 16 has a mirrored reflector. For example, with the first light coupling element 14 coupled laser light can be deflected by 90 °, for example, before it enters the optical waveguide 12, or it can be deflected with the second light coupling element 16 from the optical waveguide 12 laser light exiting by 90 °, for example, before passing through the second light coupling element 16 is coupled out, so that it can be visually perceived particularly easy by an operator. Corresponding to the green during operation laser light having a wavelength in the range of 480 nm to 560 emitting laser light source 4 are in the present embodiment, the two light coupling elements 14, 16 and the optical waveguide 12 for coupling, for forwarding and decoupling green laser light with a wavelength of 480 nm formed to 560 nm.

In this case, the jumper cable 6 is bidirectional, i. It can be coupled in a first direction via the first light coupling element 14 laser light in the optical waveguide 12 and coupled out by the second light coupling element 16, or it can in a second direction, which is opposite to the first direction, laser light on the second light coupling element 16 in the optical waveguide 12 are coupled and coupled out by the first light coupling element 14. In the illustration shown in FIG. 1, test light propagates from the first light coupling element 14 in a test light propagation direction P to the second light coupling element 16.

Reference is now additionally made to FIG. 2.

Shown is a first embodiment of one of the light coupling elements 14, 16, which in each case allows open-air coupling and uncoupling.

In this embodiment, the light coupling elements 14, 16 are formed as a fisheye lens 18 with an image angle in the image diagonal in the range of 180 ° to 220 °. The fisheye lens 18 has in the present embodiment, two along the optical axis successively arranged plano-convex lenses 20. Alternatively, convex-concave lenses may also be used.

The two plano-convex lenses 20 deflect a light beam L in such a way that it is directed into the optical waveguide 12 when the light coupling element 14, 16 acts as a light coupling element. Conversely, the two plano-convex lenses 20 scatter a light beam emerging from the optical waveguide 12 when the light coupling element 14, 16 acts as a light outcoupling element. Reference is now made to FIG. 3.

Shown is a second embodiment of the light coupling elements 14, 16. In this embodiment, the light coupling element 14, 16 on a biconvex lens 22.

In the present exemplary embodiment, the biconvex lens 22 has a mirrored lateral surface 24 and convexly shaped light entry and exit surfaces 26, 28. By the Verspieglung the lateral surface 24, a light leakage is prevented by the lateral surface during operation.

The convexly shaped light entry and exit surfaces 26, 28 are each formed hemispherical in the present embodiment, so that laser light from the entire half-space can couple into the optical waveguide 12.

The light coupling element 14, 16 may have a beam deflection device 30 with a mirrored reflector (see FIG. 1). Thus, the laser light to be coupled in or out is deflected by the beam deflection device 30, so that it can be effectively coupled into the optical waveguide 12 or can be perceived particularly visually by a surgeon visually.

The identification device 2 with the laser light source 4 and the patch cord 6 shown in FIG. 1 is used to make or change a ranking (also called a patch) in a patch panel. A patch panel, also called a patch panel or patch panel, is a connector for cables used for routing, i. for the construction of complex cable structures e.g. used in buildings. Most common are patch panels for distribution of network cables, telephone cables or fiber optic cables, especially with structured cabling.

The essential role of patch panels is to provide a connection between the rigid cables that are routed firmly in walls and the flexible patch cables. For example, a patch panel provides a series of numbered jacks (also called ports), plugged into the cables can be. On the back wall of distribution boxes, the jacks are provided with cables that connect to other patch panels or fixed outlets in the building. Shunting is called shunting or patching. In order to identify the two corresponding ends of the patching cable 6 to be transposed during maneuvering, an operator aligns the laser light source 4 so that the test light is green laser light having a wavelength, for example in the range from 480 nm to 560 nm, via the first light coupling element 14, which then acts as Light input element is used, coupled into the optical waveguide 12 and then coupled out again by the second light coupling element 16, which then serves as a light output element. Thus, in the present embodiment, the Prüflichtausbreitungsrichtung P extends from the first light coupling element 14 in the direction of the second light coupling element 16 (see Fig. 1). The decoupled light can then be visually perceived by the operator. Thus, an operator can assign the two ends of the jumper cable 6 with its associated connectors 10 each other.

The surgeon is therefore by means of the identification device 2 able to quickly, efficiently, safely and with little effort to identify the two corresponding ends of the umzusteckenden patch cable 6.

LIST OF REFERENCE NUMBERS

2 identification device

4 laser light source

6 patch cable

8 data line

10 plugs

12 optical fibers

14 first light coupling element

16 second light coupling element

18 fisheye lens

20 plano-convex lens

22 biconvex lens

24 lateral surface

26 light entry surface

28 light exit surface

30 beam deflecting device

L light beam

P test direction propagation direction

Claims

claims:

Patch cord (6) with at least one data line (8),

characterized ,

an optical waveguide (12) is arranged running at least in sections parallel to at least one data line (8), at each end of which a light coupling element (14, 16) for coupling and / or decoupling test light into and / or out of the optical waveguide ( 12) is assigned.

Patch cord (6) according to claim 1, characterized in that at least one of the light coupling elements (14, 16) has a fisheye lens (18).

Patch cord (6) according to claim 1, characterized in that at least one of the light coupling elements (14, 16) has at least one biconvex lens (22).

Patch cord (6) according to claim 3, characterized in that the biconvex lens (22) has a mirrored lateral surface (24).

Patch cord (6) according to claim 3 or 4, characterized in that the biconvex lens (22) has convexly shaped light entry and light exit surfaces (26, 28) which are formed hemispherical.

Patch cord (6) according to at least one of the preceding claims, characterized in that a Strahlumlenkeinrichtung (30) is provided, which is arranged in Prüflichtausbreitungsrichtung (P) between one of the ends of the optical waveguide (12) and one of the light coupling elements (14, 16).

Patch cord (6) according to claim 6, characterized in that the beam deflection device (30) has a mirrored reflector. Patch cord (6) according to at least one of the preceding claims, characterized in that the optical waveguide (12) is made of a plastic material.

Patch cord (6) according to at least one of the preceding claims, characterized in that the jumper cable (6) for Lichteinkoppeln, for guiding light and for light coupling of green laser light having a wavelength of 480 nm to 560 nm is formed.

0. Identification device (2) with a laser light source (4) and a jumper cable (6) according to one of the preceding claims.