DE9215593U1 - Fiber optic tester - Google Patents

Description

S/ch-H 2660

The invention relates to a fiber optic testing device for fiber optic cables consisting of a plurality of optical fibers with two ends.

Fiber optic cables are increasingly being used in technology, especially in medical technology. Since fiber optic cables are primarily made of fiber optic bundles, there is a very high risk that individual fibers will break and thus the light transmission will become increasingly poor. Detecting such errors is very difficult and also time-consuming if devices are used for this purpose, as these require a reference fiber optic cable, for example. Another problem is the very different diameters and lengths of the various cables, which make automatic measurement difficult.

The aim of the invention is to create a fiber optic testing device by means of which the extent of broken or otherwise non-functional fibers within a fiber optic cable can be easily determined even by untrained persons, so that a largely person-independent quality inspection is possible.

To solve this problem, the features of claim 1 are provided.

The idea of the invention is to feed light from a light source into one end of the light guide or light guide cable. The other end is projected via a lens system, which, for example, causes a magnification by a factor of 10, and via prisms or mirrors onto an imaging plane, in particular a ground glass screen, which

is located in a housing wall and can be easily viewed from the outside. Since the illumination intensity can be set to a suitable value, the user sees the individual end faces of the optical fibers on the screen as light or dark, depending on whether they are flawless or broken. In this way, the extent of any defect in the optical fiber can be determined at a glance and the appropriate sorting out can be carried out.

The invention is described below by way of example with reference to the drawing, in which:

Figure 1 is a perspective view of a fiber optic testing device according to the invention with a connected fiber optic cable,

Figure 2 shows a schematic cross section through a

another embodiment of a fiber optic testing device according to the invention, and the

Figures 3 Ground glass images of the front to 5 sides of three light guides, which

contain different numbers of defective optical fibers.

According to Figures 1 and 2, the optical fiber test device according to the invention has a housing 11, in the front of which two sockets 14, 15 are mounted next to or above one another. The two ends 16 and 17 of an optical fiber or optical fiber cable 13 can be plugged into these sockets 14, 15. The ends 16, 17 are preferably designed as plugs that are complementary to the sockets 14, 15.

It would also be useful to provide an adapter on both sockets 14, 15, which would allow differently dimensioned ends 16, 17 or plugs to be adapted to the sockets 14, 15.

Behind the socket 15 there is an illumination device 18, 19, which is schematically assumed to be a light source 18 and a lens 19 that parallelizes the light beam. The light source 18 is fed via a controller 27 from a power supply unit 28 that is, for example, connected to the mains voltage.

The parallel light beam 29 emanating from the lighting device 18, 19 is directed onto the front face 24 of the end 17 of the light guide 13 inserted into the socket 15, in such a way that the light enters all the light guide fibers 12 (Figures 3 to 5) evenly.

The front surface 23 of the end 16 of the light guide inserted into the socket 14 is projected from the inside via a lens 20 and two deflecting plane mirrors 21, 22 onto a ground glass screen 25 arranged in a front wall 26 of the housing 11, whereby a magnification by a factor of about 10 takes place.

A correspondingly enlarged image of the front side 23 then appears on the screen, which is shown for three light guides 13 of different quality in Figures 3 to 5, for example.

By appropriately setting the control 27 (the corresponding adjustment knob, not shown, is accessible from the outside of the housing 11), a very high-contrast image can be produced on the ground glass screen 25, in which the front areas of the individual optical fibers 12 appear bright, where the optical fibers conduct the light fed in

conduct light perfectly from the front surface 24 to the front surface 23. If one of the fibers is broken, this fiber can no longer conduct light and the corresponding image on the screen 25 appears as a dark point, as can be seen in Figure 3. If only as few black points as in Figure 3 can be seen in the image on the screen, the fiber optic cable 13 is to be classified as "good".

If a larger number of optical fibers 12 are broken, more dark end faces of optical fibers appear on the screen 25, for example as many as are shown in Figure 4. In the case of Figure 4, we would speak of a light guide that is just about usable, but which would have to be replaced if high quality requirements were met.

If a large number of optical fibers in the light guide 13 are broken, an image appears as shown, for example, in Figure 5, where large dark areas can be seen, indicating a correspondingly large number of broken optical fibers.

The invention thus allows the user to obtain a realistic picture of the quality of the tested optical fiber in the simplest way and then to decide whether this optical fiber is still usable for the desired purposes or not.

Claims (7)

S/ch-H 2660 Claims 1. Optical fiber test device for optical fibers (13) consisting of a plurality of optical fibers (12) with two ends (16, 17), with a housing (11) which has two sockets (14, 15) accessible from the outside for receiving one end (16, 17) of the optical fiber (13) in each case and has an illumination device (18, 19) arranged behind one socket (15) and an imaging device (20, 21, 22) arranged behind the other socket (14), which images the associated end face (23) of the optical fiber (13) enlarged on an imaging plane which can be seen from the outside of the housing (11). 2. Optical fiber test device according to claim 1, in which the imaging plane is formed by a ground glass screen (25) arranged in a housing wall (26), onto which an image of the relevant end face (23) is projected from the inside. 3. Optical fiber test device according to claim 1 or 2, in which the relevant front side (23) is imaged in the housing via a lens (20) and a mirror system (21, 22). 4. Fiber optic testing device according to one of the preceding claims, in which the front side (24) associated with one socket (15) is illuminated by a light source (18) via a lens arrangement (19). 5. Fiber optic testing device according to one of the preceding claims, in which the sockets (14, 15) clearly define the radial and axial position of the inserted or otherwise introduced ends (16, 17) of the light guide (13), so that targeted illumination and defined imaging are ensured. 6. Optical fiber test device according to one of the preceding claims, in which the illuminance of the light source (18) can be changed by an upstream control device (27). 7. Optical fiber test device according to one of the preceding claims, in which the imaging device (20, 21, 22) has a magnification factor of 5 to 20, in particular 8 to 12 and preferably about 10.