DE8813714U1 - Optical attenuator - Google Patents

Description

KRONiS Aktiengesellschaft

1000 Berlin 37 26.10.1988

OPTICAL ATTENUATOR

The innovation relates to an optical attenuator according to the preamble of claim i.

An optical attenuation element of the generic type is already known from DE 32 23 898 A1. The attenuation element, which is provided with disks of different transparency, is circular and is mounted in the housing so that it can rotate. The axis of rotation of the attenuation element is parallel to the axial direction of the optical fiber connection elements. The attenuation element is adjusted using a screwdriver that engages in a slot in the axis of rotation of the attenuation element and must be guided parallel to the axial direction of the optical fiber connection elements. Locking positions are provided for the individual disks of different transparency, which are formed by spring-loaded ball catches that act radially on the axis of rotation of the attenuation element. The disadvantage of this optical attenuation element is the adjustability of the attenuation element, which can only be done in the axial direction of the rotatable attenuation element. However, when installing the optical attenuator in an encapsulated optical assembly, the axis of the attenuation element often cannot be reached using a screwdriver. In addition, due to the parallelism of the screwdriver and the optical fiber, there is a risk of damaging the optical fiber when adjusting the attenuation element.

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The innovation is therefore based on the task of creating an optical attenuator of the generic type, the attenuation element of which can be operated in a simple manner without there being any hindrance due to the installation of the optical attenuator in an optical assembly and without there being any risk that the connected optical fibers will be damaged when adjusting the attenuation element.

The solution to this problem arises from the characterizing features of claim 1. The ability to move the damping element in the longitudinal direction of the housing chamber, which is longer than the damping element, and the actuation of the damping element in a direction perpendicular to the optical fiber connection elements make it possible for the damping element to be actuated without being hindered by the optical fibers and without the risk of damage. Even when the optical damping element is installed in an optical assembly, the adjustment of the damping element in a direction perpendicular to the optical fiber connection elements can be carried out safely.

Further advantageous embodiments of the innovation emerge from the subclaims. In this case, particular attention is drawn to the possibility of moving the damping element within the housing chamber by means of a screwdriver or similar engaging in a transverse slot of the damping element.

The innovation is explained in more detail below using an example of an optical attenuator shown in the drawings. They show:

Fig. 1 a horizontal cross-section through the attenuator in the axis of the optical fiber connection elements,

Fig. 2 a vertical cross section through the

Damping element in the axis of the fiber optic connection elements and

Fig _. 3 shows a cross-section through the attenuation element in the longitudinal direction of the housing chamber and transverse to the axial direction of the optical fiber connection elements.

The optical attenuation element consists of a housing 1, a base plate 2, a housing cover 3 and LWL (optical waveguide) connection elements 4 arranged on opposite sides of the housing. The base plate and the housing cover 3 are glued to the housing 1. The housing is fastened in a frame (not shown) by means of screws (not shown) which pass through holes 5. A housing chamber 7 is formed in the housing 1 transversely to the axial direction 6 of the optical waveguide connection elements, in which a damping element 8 is adjustably mounted.

consists of a disc with surfaces of different transparency. The housing chamber 7 is approximately twice as long as the damping element 8, which is guided along the long side walls of the housing chamber 7.

In the bottom of the housing 1, holes 9 are formed along the housing chamber; their cross-section is slightly reduced in the area of the opening facing the housing chamber 7. Balls 10 are inserted into the holes 9,

which are under the action of compression springs 11, which are supported between the balls 10 and the base plate 2 closing the holes 9 at the bottom. On the underside of the damping element 8, locking grooves 12 are formed, the distance between which in the embodiment is half as large as the distance between the balls 10. By locking the balls 10 into the locking grooves 12, the damping element 8 can be positioned precisely in a variety of positions within the housing chamber 7.

2In order to adjust the damping element 8 within the housing chamber 7, a transverse slot 13 is made in the damping element 8 on the top side of the damping element facing away from the locking grooves 12. The housing cover 3, which guides the top side of the damping element 8 and which protrudes into the housing chamber 7 with a central projection, is provided with a longitudinal slot 14 through which the transverse slot 13 serving as an actuating element for the damping element 8 can be reached by means of a tool, in particular a screwdriver, in order to adjust the damping element in the longitudinal direction of the housing chamber 7.

In an embodiment not shown, a nose attached to the top of the damping element passes through the longitudinal slot and can be operated manually from the outside of the optical damping element without tools.

The two optical fiber connection elements 4 are made of sleeve bodies 15 that are firmly inserted into the sides of the housing and through which the optical fibers are guided into the housing 1. Threaded sleeves 16 are glued onto the sleeve bodies 1*5 and are directly attached to the free

The end of the sleeve bodies 15 are provided with O-rings 17 on their inside to seal the optical fibers. The union nuts of optical fiber couplings (not shown) are screwed onto the threaded sleeves 16.

Parallel to the housing chamber 7, in the area of the fiber optic connection elements 4, further chambers 18 are formed, in which lenses 19, in particular GRIN lenses, are inserted, which serve to expand or concentrate the beams guided through the fiber optic cables (FOC). The lenses 19 are glued to the housing 1 within the chambers 18 after adjustment in the optical beam path of the fiber optic cables.

Claims (9)

it- -tv KRONE Aktiengesellschaft 1000 Berlin 37 26.10.1988 PROTECTION CLAIMS 1. Optical attenuation element comprising a housing with optical fiber connection elements arranged on opposite sides of the housing and an attenuation element of different transparency which is adjustably mounted in a housing chamber arranged transversely to the axial direction of the optical fiber connection elements, characterized in that the housing chamber (7) is longer than the attenuation element (8) and that the attenuation element is arranged in the longitudinal direction of the Housing chamber (7) in a perpendicular direction to the LWL connection elements (4) adjustable and movable is stored. 2. Damping member according to claim 1, characterized in that the damping element (8) is adjustable and lockable by means of spring-loaded balls (10) engaging in locking grooves (12) of the damping element (8). 3. Damping element according to claim 1 or 2, characterized in that the housing chamber (7) is provided with a longitudinal slot (14) for the engagement of an actuating element for adjusting the damping element (8). 4. Damping element according to claim 3, characterized in that the longitudinal slot (14) is formed within a housing cover (3) closing the housing chamber (7). 5. Damping member according to claim 3 or 4, characterized in that a transverse slot (13) is formed as the actuating element in the side of the damping element (8) facing the longitudinal slot (14). 6. Damping element according to claim 3 or 4, characterized in that a nose which passes through the longitudinal slot (14) is formed on the damping element as an actuating element. 7. Damping element according to one of claims 1 to 6, characterized in that balls (10) loaded by springs (11) are mounted in bores (9) in the bottom of the housing (1), which engage in locking grooves (12) on the underside of the damping element (8). 8. Attenuation element according to one of claims 1 to 7, characterized in that the optical fiber connection elements (4) are formed from sleeve bodies (15) fixedly attached to the housing (1) and optical fiber coupling elements that can be firmly placed on these. 9. Damping element according to one of claims 1 to 8, characterized in that on both sides of the housing chamber (7) for the damping element (8) there are receiving chambers (18/ for lenses (19) which are glued into the receiving chambers (19) after the depth of alignment.