DE202011050738U1 - Test device for optical fibers - Google Patents

Abstract

Test device for optical waveguides, comprising: - a housing (10), in the interior of which a receiving space (101) is delimited, the housing (10) having an optical waveguide receiving part (102); - A test arrangement (11) which is accommodated in the receiving space (101) and comprises at least a plurality of photodiodes (111); - A clamping device for an optical test (12) for clamping an optical waveguide line (2), which clamping device is received in the receiving space (101) and has an upper and a lower jaw (121, 122) between which the optical waveguide line (2) is clamped can, wherein the upper jaw (121) has an arch-shaped elevation (121a) and the lower jaw (122) has an arch-shaped indentation (122a) matching the profile of the arch-shaped elevation (121a), the photodiodes (111) in the lower jaw (122) are arranged; - a light shielding assembly (123) received in the receiving space (101) and having a light shielding main body (123a) and two elastic light shielding parts (123b), the two elastic light shielding parts ...

Description

The present invention relates to a test device for optical waveguides, in particular a test device for optical waveguides for testing and repairing an optical waveguide line.

Optical fibers are means made of glass or plastic fibers for transmitting light waves. As a transmission medium for communication systems, the optical waveguides on a large broadband and a high transmission speed and are now used mainly as a transmission medium for networks for use. When mounting the fiber optic cables, a large amount of patch cords are put on, with different workers having different ways of connecting the patch cords; In addition, patch cords from different manufacturers are manufactured according to standards, so that the design and functions of patch cords from different manufacturers differ. For the reasons mentioned above, the workers for the cable system can not quickly determine the corresponding, correct connection point for each fiberglass patch cable, which leads to inefficient cable installation and withdrawal. In addition, optical fibers are fragile and have low mechanical strength, wherein the fiber core is made of glass - a fragile material - with a small wire diameter, so that the optical fiber in the cable system can not be pulled with great force and no label or label in addition to the cladding can be added, so that it is not easy to detect the quality of a particular fiber optic cable in the system of optical fibers; Further, the conventional optical fiber inspection apparatus has the disadvantages that light leakage in inspection and damage of the optical fiber cable upon operation are easy, resulting in incorrect test results and prolonging the replacement time of the optical fibers, so that the communication quality suffers and some Staff costs and time for the repair work to be wasted.

The invention has for its object to provide a test apparatus for optical fibers, with the quality of the optical fiber cable can be quickly detected as good or defective goods or the direction of entry of a Lichtleitfasersignals; In addition, the optical fiber inspection apparatus is designed to prevent light leakage, so that the inspection personnel can accurately read and judge a test signal, thereby reducing the time for testing and repair work.

The object is achieved by an optical fiber testing apparatus comprising a housing, an inspection assembly, a clamper for optical inspection, a light shielding assembly, and a guide assembly. Inside the housing, a receiving space is defined, wherein the housing has an optical waveguide receiving part; the test arrangement comprises at least a plurality of photodiodes; the optical test jig for jamming an optical fiber line is received in the receiving space and arranged in alignment with the optical fiber receiving part, the optical test jaw having upper and lower jaws between which the optical fiber line can be clamped, the upper one Cheek has a round-arched elevation and the lower jaw has a profile coincident with the circular arc-shaped elevation round arch-shaped recess, wherein the photodiodes are arranged in the lower jaw; the light shielding assembly comprises a light shielding main body and two elastic light shielding members, the two elastic light shielding members being disposed on the light shielding main body, the two lateral sides of the lower jaw being respectively formed in correspondence with the two elastic light shielding members; the guide assembly extends outside the housing and is connected to one of the two jaws, the upper and lower jaws being brought close to each other by the guide assembly to test the optical fiber line.

The invention has the following advantages: in the optical waveguide test device according to the invention, the two elastic light-shielding parts each coincide with the two lateral sides of the lower jaw, whereby mutual interference of an external light source and a light signal of the optical waveguide line can be prevented, so that the quality of the Fiber optic cable (as good or defective goods) can be detected quickly and accurately; In addition, the optical waveguide test apparatus according to the invention is suitable for clamping optical waveguide lines with different inner cladding diameters and enables time-saving, simple and rapid testing of the optical waveguide line.

In the following, the technical contents, measures and functions of the present invention will be explained in more detail with reference to the detailed description and the accompanying drawings. However, the invention is not limited to the description and the accompanying drawings. Show it:

1 a perspective view of an inspection device according to the invention for optical fibers in the assembled state,

2 a perspective view of the test apparatus according to the invention for optical fibers in the disassembled state,

3 a further perspective view of the test device according to the invention for optical fibers in the disassembled state,

4A a schematic representation of a clamping device for an optical inspection of the test apparatus according to the invention for optical fibers,

4B a sectional view of the clamping device for an optical inspection of the test apparatus according to the invention for optical fibers,

5A a schematic representation of the clamping device for optical testing of the test apparatus for optical waveguide according to the invention in use, and

5B a sectional view of the clamping device for an optical inspection of the test apparatus according to the invention for optical fibers in use.

It is referring to 1 to 3 taken. As in 2 shown comprises the test device for optical waveguides according to the invention 1 a housing 10 , an exam arrangement 11 , a light-shielding arrangement 123 , a clamping device for a visual inspection 12 for clamping an optical fiber cable 2 (please refer 4A ) and a leadership arrangement 13 ,

As in 1 is shown inside the case 10 a recording room 101 demarcated, with the housing 10 an optical fiber receiving part 102 having. As in 2 can show the exam arrangement 11 , the clamping device for a visual inspection 12 and the leadership arrangement 13 in the recording room 101 be received, wherein the test optical fiber cable 2 in the optical fiber receiving part 102 can be included. The exam arrangement 11 includes at least several photodiodes 111 , z. As PIN photodiodes (P-layer, intrinsic-layer, N-layer photodiodes) or avalanche photodiodes (APD), and serves to detect and test the optical fiber cable 2 ,

As in 2 shown, the clamping device for a visual inspection 12 in coordination with the optical waveguide receiving part 102 arranged (see 1 ), wherein the clamping device for a visual inspection 12 an upper and a lower jaw 121 . 122 between which the optical fiber line (not shown) can be clamped, wherein the guide arrangement 13 to one of the two jaws 121 . 122 connected; in this embodiment, the guide assembly 13 to the upper cheek 121 connected. At the rear end of the upper cheek 121 protrudes a round-arched elevation 121 forth, and at the front end of the lower jaw 122 is a profile with the round-arched elevation 121 matching arched indentation 122a educated; when the upper and the lower jaw 121 . 122 For the purpose of testing the optical fiber line, they may bend the previously described structural design in a non-destructive manner so as to temporarily destroy the optical path of the total reflection of the optical fiber line, with some of the light from the bending point being tangential along the direction of travel the optical fiber cable runs out and thus from the test arrangement 11 is detected, so that the transmission direction of the optical waveguide line, the presence of the function for transmitting a light signal of the optical waveguide line and the quality of the optical waveguide line can be determined with the test device according to the invention. For example, the photodiodes 111 detect a light signal in the normal transmission state of the optical waveguide line and thereby determine the transmission direction of the light; when the photodiodes 111 can not detect a light signal, this means that the transmission of the optical fiber cable is interrupted. The amount of light leakage depends on the curvature of the optical fiber cable; therefore, the round-arched elevation 121 the upper cheek 121 be trained in accordance with the needs of different tests to varying degrees in order to meet the testing needs of different types of optical fiber cables. Preferably, the photodiode is 111 in favor of the test under the lower jaw 122 arranged.

It is worth noting that the light shielding arrangement 123 a light-shielding main body 123a and two elastic light-shielding parts 123b wherein the light-shielding main body 123a on the upper cheek 121 is mounted; the two elastic light-shielding parts 123b are at the light-shielding main body 121 arranged, with the two lateral sides of the lower jaw 122 each in coordination with the two elastic light-shielding parts 123b are trained; when the upper and the lower jaw 121 . 122 approach each other, the two elastic light-shielding parts 123b each with the two lateral sides of the lower jaw 122 complementarily assembled and clamp the fiber optic cable to be tested 2 so determines that the emerging light signal at the bending point of the optical fiber cable 2 and external light sources do not interfere with each other, thereby avoiding an influence on the test data of the light signal, and thus the accuracy, the reliability and the credibility of the test can be significantly increased. Furthermore, the guide arrangement 13 thanks to the elasticity of the elastic light-shielding parts 123b the distance between the upper and the lower jaw 121 . 122 Adjust appropriately so that both a large diameter optical fiber line and a small diameter optical fiber line into the optical fiber receiving portion 102 can be used (see 1 ) to perform a signal check. Thus, the test of the optical fiber cable can be time-saving, easy and fast perform.

The following is based on 1 to 3 the embodiment of the test device according to the invention for optical waveguides explained. Here are the profile of the light shielding arrangement 123 and their position relative to the upper jaw 121 not limited; the conception of the light shielding arrangement 123 the underlying principle is to be able to achieve the best light-shielding effect. How out 2 can be seen, the light-shielding arrangement 123 on the upper surface of the upper jaw 121 be arranged, wherein the two lateral sides of the light-shielding main body 123a each with a mounting part 123c are provided, wherein the two elastic light-shielding parts 123b each at the two mounting parts 123c can be mounted. Here, the material and the mounting manner of the elastic light-shielding parts 123b not limited; In this embodiment, the mounting parts 123c as mounting recesses are made by the top of the light-shielding main body 123a bent down in the form of an inverted L; In addition, the light-shielding main body 123a through the mounting parts 123c stable at the front end of the upper jaw 121 support; the elastic light-shielding parts 123b can be made of foam and removable by gluing to the mounting hardware 123c be mounted so that they can be quickly replaced and repaired depending on the state of use.

The lower cheek 122 is with a plurality of photometric holes 122b provided in which the photodiodes 111 can be taken to test a light signal (not shown in the drawing) of the optical fiber cable. Here are the profile, the number and the arrangement of the Lichtmessungslöcher 122b not limited. In this embodiment, two light measuring holes 122b and two photodiodes 111 provided, wherein the light measuring holes 122b can be arranged funnel-shaped to facilitate the examination of the light signal at the bending point of the optical fiber cable. It is worth noting that the two lateral sides of the lower jaw 122 so extend forward so that two support blocks 122c in coordination with the elastic light-shielding parts 123b form; in this embodiment, the support blocks 122c slightly L-shaped and are the elastic light-shielding parts 123b with the mounting parts 123c consistently formed in the form of a slightly upturned L; when the upper and the lower jaw 121 . 122 approach each other, the support blocks 122c and the elastic light-shielding parts 123b close to each other to avoid that external light source disturb the Prüfug.

The leadership arrangement 13 includes a guide plate 131 , a stop 132 and a spring element 133 , One side of the guide plate 131 can go to one of the two cheeks 121 . 122 be connected, in this embodiment, the guide plate 131 to the upper cheek 121 is connected and on the other side of the guide plate 131 a guide arm 131 is formed, so that the spring element 133 over the guide arm 131 can be pulled; the spring element 133 is longer than the guide arm 131 formed and provides a resilient restoring force through which the upper and lower jaw 121 . 122 separate each other. As in 2 shown is the case 10 with a sliding groove 103 provided so that the stop 132 through the sliding groove 103 of the housing 10 passed and then to the guide plate 131 can be connected, the test personnel by the sliding of the stop 132 along the sliding groove 103 the distance between the upper and the lower jaw 121 . 122 can determine. As in 3 shown, the guide plate can 131 with a plurality of positioning pins 131b be provided; the light shielding arrangement 123 can with a plurality of positioning protrusions 123d be provided; the upper cheek 121 is with a plurality of positioning through holes 121b provided by the positioning projections 123d and the positioning pins 131b can be passed vertically through; in the state in which the light shielding arrangement 123 , the upper cheek 121 and the guide plate 131 Assembled with each other, can be a lateral side of the stop 132 through a window 131c on the guide plate 131 passed through and so with the guide plate 131 be screwed together so that the test personnel by means of the guide assembly 13 the upper cheek 121 to the lower cheek 122 closer to the test.

Between the upper and the lower cheek 121 . 122 can be a wavy elastomer 124 be arranged, the front end contoured with the round-arched elevation 121 at the rear end of the upper cheek 121 coincides and its rear end contoured with the round arch-shaped recess 122a at the front end of the lower jaw 121 matches the material and the way of mounting the elastomer 124 are not restricted. According to this embodiment 2 is the elastomer 124 made of foam and on the upper cheek 121 glued. It should be noted that the elastomer 124 with a narrow slot 124a is provided, which is parallel to the circular arc-shaped recess 122a is arranged and has a width which is smaller than the diameter of the optical fiber cable to be tested, so that the elastomer 123 when approaching the upper and the lower jaw 121 . 122 as a shock-absorbing, slip-resistant pad for the upper jaw 121 and the optical fiber line (not shown) may serve to rigidly destroy the optical fiber line due to direct contact with the upper jaw 121 to avoid, as well as the optical fiber line position, to avoid slippage of the optical fiber cable, which can lead to an unreliable test result.

Next is out 2 and 3 seen that the case 10 the test device for optical waveguides according to the invention 1 also a first upper lid 104 , a second upper lid 105 , a protective undercover 106 , a battery lower lid 107 and a blocking plate 108 includes. The battery lower cover 107 is separable to the protective undercover 106 and the second upper lid 105 connected, and the circumference of the locking plate 108 is attached to the protection lower lid 106 and the second upper lid 105 connectable, leaving the second upper lid 105 , the batteries under lid 107 and the lock plate 108 together a battery compartment 109 for recording batteries (not shown) serving as a power source for the optical fiber inspection apparatus 1 serve. The first upper lid 104 serves to protect the components of the clamping device for a visual inspection 12 and to protect the photometric holes 122b from dust. The battery lower cover 107 can further with a fastening part 107a Be provided with the guide arm 131 the guide plate 131 and the fastening part 107a when approaching the upper and the lower jaw 121 . 122 support each other and thus position themselves.

As in 2 shown includes the exam arrangement 11 the test device for optical waveguides according to the invention 1 Furthermore, a test board 112 , a plurality of electronic components (not shown) and a display screen (not shown), the electronic components and the display screen both to the test board 112 can be connected. In this embodiment, the housing 10 further comprising a plurality of housing openings 110 Be provided, and the housing 10 is a front panel 14 with a plurality of front panel openings 141 arranged, with the front panel 14 with a plurality of test buttons 142 is provided, with the test buttons 142 , the electronic components and the display screen all to the test board 112 are electrically connected; the test buttons 142 are in coordination with the front panel openings 141 arranged and look from the top surface of the front panel 14 with the test personnel operating the test buttons to test an optical fiber signal. After processing the signal through the test board 112 the exam information is displayed on the display screen so that the examiner can read and judge it quickly. In this embodiment, the lower jaw 122 to the examination board 112 firmly connected, and the upper jaw 121 shifts through the leadership arrangement 13 to the lower cheek 122 ,

For the operation of the test device for optical waveguides according to the invention 1 will be on 4A to 5B directed. As in 4A and 4B is shown, for testing the optical fiber cable 2 first the fiber optic cable 2 for supporting on the two support blocks 122c the lower cheek 122 brought; when the upper cheek 121 the lower cheek 122 approaches, the elastomer will 125 first on the fiber optic cable 2 support, then the elastomer 125 compressed, partly in the narrow slot 124a enters and thereby with the upper cheek 121 comes into contact. This is followed by the upper jaw 121 the fiber optic cable 2 approaches and pushes them down, as in 5A and 5B shown, the upper and the lower jaw can 121 . 122 in the meantime, allow part of the light (the optical fiber signal) out of the fiber optic cable 2 exit. It is noteworthy that the elastic light-shielding parts 123b and the support stands 122c the lower cheek 122 the opposite sides of the optical fiber cable 2 envelop completely and the optical fiber receiving part 102 (please refer 4A ) through the light shielding assembly 123 , the upper cheek 121 , the lower cheek 122 , the case 10 and the support stands 122c is sealed as an almost completely opaque space (not shown), whereby it can be ensured that the light signal is completely checked by the photodiodes, so that the inspection precision can be increased considerably.

How out 2 As can be seen, the test personnel can also apply a force to the stop 132 exercise the distance between the upper and the lower jaw 121 . 122 to adjust, which is on the guide plate 131 arranged spring element 133 on the fastening part 107a of the battery lower cover 107 can support; when the guide plate 131 to the battery lower cover 107 shifts, the spring element 133 pressed together; after the test, only the stop 132 be solved so that the upper jaw 122 by the resilient restoring force of the spring element 133 automatically reset and ready for the next test; Thus, the test takes place time, energy saving, easy and fast. The test device for optical waveguides according to the invention 1 has a simple and compact design and is suitable for fiber optic cables of various dimensions; In addition, the fiber optic cable can be 2 to test easily in tester 1 insert so that accidental damage to the fiber optic cable to be tested 2 are avoidable.

• 1. mit der erfindungsgemäßen Prüfvorrichtung für Lichtwellenleiter ist vermeidbar, dass externe Lichtquellen und Lichtsignale der Lichtwellenleiterleitung sich einander stören, so dass die Wahrscheindlichkeit der Lichtleckage erheblich reduziert werden kann; dadurch kann das Prüfpersonal schnell und präzise die Qualität der Lichtwellenleiterleitung und die Übertragungsrichtung des Lichtsignals schnell feststellen;
• 2. die erfindungsgemäße Prüfvorrichtung für Lichtwellenleiter ist einfach und kompakt konstruiert und eignet sich zum Festklemmen von Lichtwellenleiterleitungen mit verschiedenem innerem Ummantelungsdurchmesser, so dass die Photodioden die Signalprüfung der Lichtwellenleiterleitung zeitsparend, einfach und schnell durchführen können;
• 3. bei der erfindungsgemäßen Prüfvorrichtung für Lichtwellenleiter 1 kann das Prüfungsergebnis schnell gelesen und beurteilt werden, wodurch die Zeit für die Prüfung und Reparatur reduzuert werden kann; und
• 4. die Lichtwellenleiterleitung 2 lässt sich zum Prüfen leicht in die Prüfvorrichtung 1 einsetzen, so dass versehentliche Schäden der zu prüfenden Lichtwellenleiterleitung 2 vermeidbar sind.

The test device according to the invention for optical waveguides has the following advantages:

• 1. with the test device for optical waveguide according to the invention is avoidable that external light sources and light signals of the optical waveguide interfere with each other, so that the probability of light leakage can be significantly reduced; thereby, the inspection personnel can quickly and accurately determine the quality of the optical fiber line and the transmission direction of the light signal quickly;
• 2. the optical waveguide test apparatus according to the invention is simple and compact in design and is suitable for clamping fiber optic cables with different inner sheath diameter, so that the photodiodes can perform the signal testing of the optical waveguide time-saving, easy and fast;
• 3. in the test apparatus for optical waveguide according to the invention 1 the test result can be read and evaluated quickly, reducing the time required for testing and repair; and
• 4. the fiber optic cable 2 can be easily inserted into the test device for testing 1 insert so that accidental damage to the fiber optic cable to be tested 2 are avoidable.

The above description represents a preferred embodiment of the invention and is not intended to limit the claims. All equivalent changes and modifications that may be made by those skilled in the art in accordance with the description and drawings of the invention are within the scope of the present invention.

Claims (10)

Optical waveguide testing device comprising: - a housing ( 10 ), in the interior of which a receiving space ( 101 ) is demarcated, wherein the housing ( 10 ) an optical waveguide receiving part ( 102 ) having; - an examination order ( 11 ) in the reception room ( 101 ) and at least a plurality of photodiodes ( 111 ); A clamping device for an optical test ( 12 ) for clamping an optical waveguide line ( 2 ), which clamping device in the receiving space ( 101 ) and an upper and a lower jaw ( 121 . 122 ), between which the optical waveguide line ( 2 ), the upper jaw ( 121 ) a round-arched survey ( 121 ) and the lower jaw ( 122 ) a profile with the round-arched elevation ( 121 ) matching arcuate indentation ( 122a ), the photodiodes ( 111 ) in the lower jaw ( 122 ) are arranged; A light-shielding arrangement ( 123 ) in the reception room ( 101 ) and a light-shielding main body ( 123a ) and two elastic light-shielding parts ( 123b ), wherein the two elastic light-shielding parts ( 123b ) at the light-shielding main body ( 123a ) are arranged, wherein the two lateral sides of the lower jaw ( 122 ) in each case in coordination with the two elastic light-shielding parts ( 123b ) are formed; and - a leadership arrangement ( 13 ) in the reception room ( 101 ) and is located outside the housing ( 10 ), wherein the guiding arrangement ( 13 ) to one of the two jaws ( 121 . 122 ) connected; characterized in that the upper and lower jaws ( 121 . 122 ) by the management order ( 13 ) are brought close to each other to the optical fiber line ( 2 ) to consider. Test device according to claim 1, characterized in that the two lateral sides of the light-shielding main body ( 123a ) each with a mounting part ( 123c ), the two elastic light-shielding parts ( 123b ) at the two mounting parts ( 123c ) are mounted. Test device according to claim 2, characterized in that the lower jaw ( 122 ) with a plurality of light measuring holes ( 122b ), wherein the two lateral sides of the lower jaw ( 122 ) extend forward so that two support blocks ( 122c ), the photodiodes ( 111 ) in the photometering holes ( 122b ) are arranged, wherein the two support blocks ( 122c ) in coordination with the elastic light-shielding parts ( 123b ) are formed. Test device according to claim 3, characterized in that the guide arrangement ( 13 ) a guide plate ( 131 ), a stop ( 132 ) and a spring element ( 133 ), wherein one side of the guide plate ( 131 ) to one of the two jaws ( 121 . 122 ) is connected, wherein on the other side of the guide plate ( 131 ) a guide arm ( 131 ), wherein the spring element ( 133 ) over the guide arm 131 is pulled, the housing ( 10 ) with a sliding groove ( 103 ), the stop being ( 132 ) through the sliding groove ( 103 ) of the housing ( 10 ) and then to the guide plate ( 131 ) connected. Test device according to claim 4, characterized in that the guide plate ( 131 ) with a plurality of positioning pins ( 131b ) and the light shielding arrangement ( 123 ) having a plurality of positioning projections ( 123d ), the upper jaw ( 121 ) having a plurality of positioning through-holes ( 121b ), by which the positioning projections ( 123d ) and the positioning pins ( 131b ) are guided vertically through. Test device according to claim 1, characterized in that between the upper and the lower jaw ( 121 . 122 ) an elastomer ( 124 ) arranged with a narrow slot ( 124a ), which is parallel to the circular arc-shaped indentation ( 122a ) is arranged. Test device according to claim 1, characterized in that the housing ( 10 ) further comprises a first upper lid ( 104 ), a second upper lid ( 105 ), a protective lower cover ( 106 ), a battery lower cover ( 107 ) and a blocking plate ( 108 ), wherein the battery lower cover ( 107 ) separable to the protective lower cover ( 106 ) and the second upper lid ( 105 ), wherein the circumference of the blocking plate ( 108 ) to the protective lower cover ( 106 ) and the second upper lid ( 105 ) is connectable, wherein the second upper lid ( 105 ), the battery lower cover ( 107 ) and the blocking plate ( 108 ) together a battery compartment ( 109 ). Test device according to claim 1, characterized in that the test arrangement ( 11 ) a test board ( 112 ) to which the photodiodes ( 111 ) are electrically connected. Test device according to claim 8, characterized in that the housing ( 10 ) further comprising a plurality of housing openings ( 110 ) is provided. Test device according to claim 9, characterized in that on the housing ( 10 ) a front panel ( 14 ) with a plurality of front panel openings ( 141 ) is arranged, wherein the front panel ( 14 ) with a plurality of test buttons ( 142 ) attached to the test board ( 112 ) is electrically connected, wherein the test buttons ( 142 ) in coordination with the front panel openings ( 141 ) and from the upper surface of the front panel ( 14 ) look out.

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