CS255178B1 - Measuring optical attenuator - Google Patents

Abstract

The solution relates to the field of measuring optical attenuators with regard to the mechanical arrangement of the tuning elements of the attenuator and solves the problem of horizontal and vertical misalignment of the axes of the optical elements (61a, 61b) and optical connectors (31a, 31b), as well as the axial movement of the optical elements (61a, 61b) with exceptional accuracy and long-term stability. The essence of the solution lies in the fact that the flexible core (1) of the attenuator with a horizontally situated base plate (10) with a series of vertical ribs (la to lf), of which two inner pairs of ribs are provided with tuning screws (2al to 2dl and 2a2 to 2d2) is preferably made of one piece of material, while the flexibility of the tunable ribs (la to ld) is achieved by expansion gaps (14, 15) introduced into the flexible core (1) of the attenuator from two opposite sides, and by the first and second relief holes (12 and 13) in each rib (la to ld). To ensure the change in attenuation of the transmitted light beam, the attenuator is provided with two gear disks (32a, 32b) with optical filters, which are in engagement with the counter wheels (33a, 34) of the transmission mechanism, the gear disks (32a, 32b) being located on the support shaft (81) and the counter wheels (33, 34) on the tuning shafts (82, 83). The solution can be advantageously used also for other optical devices, in which it is necessary to adjust the axes of individual optical elements to a common axis.

Description

The present invention relates to a measuring optical attenuator for use in the field of optoelectronics.

Measuring optical attenuators are known, both fixed, with constant attenuation, and tunable with variable attenuation. The attenuation rate is usually achieved by incorporating different coaxial filters between the ends of the two optical fibers or the inclined filters with variable angle of inclination. The design of each type of attenuator is conditioned by the incorporation of the optical system, i.e. the input and output connectors, the optical elements and the filters into its supporting structure, on which its operational reliability depends.

The shortcomings of the existing measuring optical attenuator designs are that the extraordinary precision requirements - alignment and parallelism of the beam are usually realized using many parts requiring very demanding manufacturing technology, which makes the whole device extremely delicate and expensive. All known attenuator solutions have optical elements, i.e., input and output connectors, and optical elements in a common axis, with the required tolerance below one micrometer.

To set precise positions of individual elements it is necessary to use differently complicated mechanical systems in lever, screw, sliding, rotating etc. As it is a solution intended in its final arrangement for measuring purposes, it is difficult to maintain high demands on mechanical stability and stiffness, resistance to temperature changes, dust-tightness and time stability, whose strict requirements for elimination of clearances in mechanisms, limitation of thermal expansion of components and undesirable springing, use of non-aging materials and chemical influences.

The aforementioned drawbacks are overcome by the measuring optical attenuator of the invention comprising an optical system consisting of two discs with optical filters for adjusting the attenuation rate of the transmitted light beam, the input and output connectors, the first and second optical members.

SUMMARY OF THE INVENTION The horizontally situated base plate of a flexible attenuator core having a series of vertical ribs, perpendicular to the axis of the attenuator optical system, is parallel to the base plate of the flexible attenuator, two of which outer form a first bearing rib and a second bearing rib. The four inner ribs, provided on opposite sides of the flexible core with one horizontal expansion gap, form one outer pair of tunable fins with clamping sleeves for receiving the input connector and the output connector, and a second inner tunable pair for retaining the first optical member and the second optical member.

All four tunable ribs are provided at their upper opposing spans with tuning screws for vertically and horizontally varying the positions of the input connector, output connector, first optical member and second optical member axes. Optical filter discs of the optical system, located in the gap between the inner pair of ribs and the gears of the gear mechanism, are mounted on shafts housed in the housings of the first bearing rib and the second bearing rib. All four tunable ribs are provided with holes larger than the diameter of the shafts at the passage points of the shafts of the transmission mechanism.

The two opposed horizontal expansion gaps in the flexible core of the attenuator terminate in at least all tunable ribs with a first relief opening and a second relief opening. The first rib of the outer pair of tunable ribs is provided with a clamping sleeve with resilient jaws to receive the guide cylindrical portion of the input connector without play. On the outer conical part of the elastic jaws is fitted a sleeve ring connected by the control screws to the first tunable rib. The second rib outer of the tunable ribs is provided with similar elements with an output connector and is arranged symmetrically to the center plane of the flexible attenuator core.

The first rib of the inner pair of tunable ribs is provided with a tunable housing with a first optical member which is slidably received in the guide housing. On its circumference, it is provided with two wedge grooves, on whose remote sides the tapered tips of the set screws passing through the threads in the guide bushing, and the larger holes in the upper part of the first of the inner pair of tunable ribs. The second, tunable rib is provided with similar elements with a second optical member arranged symmetrically to the center plane of the flexible attenuator core.

The transmission mechanism consists of three shafts, of which on the first support shaft are located two discs with optical filters, provided with gears on the circumference, which fits in the first disc to the counterwheel gear located on the second - tuning shaft for step tuning optical filters, and fits into the counterwheel gear, located on the third tuning shaft for fine tuning of the optical filters.

The advantages of the measuring optical attenuator according to the invention arise from the fact that the flexible core of the attenuator is made of one piece of material, as a result of which the individual functional parts of the flexible core exhibit perfect positional stability conditional on optimal accuracy of the attenuator as a whole. In a given design, the attenuator consists of a minimum number of components, which makes it easy to assemble, while attaining the high functional accuracy of the attenuator by virtue of the foregoing, manufacturing requirements for the accuracy of its individual components are moderate.

The design of the attenuator ensures not only its considerable resistance to adverse mechanical influences, but also its long-term reliability and functional stability over a wide temperature range. Adjusting all optical elements in both vertical and horizontal directions, with an accuracy of more than one micrometer, is easy. The solution as a whole ensures easy access to all parts of the attenuator, especially its tuning elements. The attenuator's dust-tightness can be reliably ensured by a very simple cover.

The measuring optical attenuator of the present invention will be described in greater detail below with reference to the accompanying drawings, in which: Figure 1 shows the overall configuration of a measuring optical attenuator consisting of an integral flexible core consisting of a base plate, two pairs of tunable ribs provided with tuning screws and one pair of bearing Fig. 2 shows the front view of the measuring optical attenuator showing the flexible core and the connectors with their bushings, and the discs with optical filters for tuning the attenuator; 2 is a side view showing horizontal expansion gaps terminated by relief holes and the flexible portions of the tunable fins; FIG. 4 shows the input connector and the clamping sleeve provided with flexible jaws; evleč Nym ring, control ring and the bolts and FIG. 5 illustrates a mechanism for the axial tuning of the first optical element with the guide sleeve housing and tunable by adjusting screws.

The measuring optical attenuator according to the invention in the overall view shown in FIG. 1 is constituted by both a flexible core and an attenuator in which a gear mechanism is incorporated; this part represents the essence of the invention. It is further comprised of an optical system which does not fall within the scope of the invention.

The optical system located in the flexible attenuator core 1 comprises an input connector 31a, an output connector 31b, a first optical member 61a, a second optical member 61b, an attenuator step tuning disc 32a, and an attenuator step filter optical disc 32b. The flexible attenuator core, in which the optical system and the transmission mechanism are mounted, consists of a horizontally situated base plate 10, a series of vertical ribs 1a to 1f, perpendicular to the axis of the optical system parallel to the base plate 10 of the flexible core 1. ^ attenuator. The two outer ribs 1a-1f form a first lo255178 stroke rib 1e and a second bearing rib 1f. The four internal tunable ribs 1a-1d shown in Figures 1 and 3, provided on opposite sides of the flexible attenuator core 2 with one horizontal expansion gap 14, 15, form one outer pair of tunable ribs 1a and 1b with clamping sleeves 3a, 3b for mounting. an input pair 31a and an output connector 31b, and a second inner pair of tunable ribs 1c, 1d for receiving the first optical member 61a and the second optical member 61b, as shown in Figure 2.

All four tunable ribs 1a-1d are provided at their upper opposite corners with tuning screws 21a-2d1 for vertically repositioning the axes of the input connector 31a, the output connector 31b, the first optical member 61a, the second optical member 61b of the optical system, and the tuning screws 2a2. 2d2 for horizontally varying the axis positions of the input connector 31a, the output connector 31b, the first optical member 61a and the second optical member 61b of the optical system shown in Figures 1 and 2.

The optical filter discs 32a, 32, located in the gap 11 between the inner pair of ribs, are mounted on the support shaft 81 and on the tuning shafts 82, 83 are counter-rotating 33, 34 of the transmission mechanism, all shafts 81-83 being housed in the housings of the first. 2 and 3. All four tunable ribs 1a-1d are provided with holes larger than the diameter of said shafts at the points of passage of the shafts 81-83 of the gear mechanism, so that during tuning , that is, the deflection of the tunable fins with the optical elements has not been in contact with the shafts of the gear mechanism.

The two opposing horizontal expansion gaps 14, 15 and the respective first relief holes 12 and the second relief holes 12 'are advantageously formed not only in the tunable ribs 1a-1d but also in the first bearing rib le 1 with regard to the technological processing of the flexible attenuator core 2. and in the second bearing rib 12 as shown in Figures 1 and 3.

The first tunable la rib pair of outer ribs tunable la, lb, ³ and provided with a clamping sleeve with resilient jaws 3a 3Al. On the outer conical portion of the elastic jaws 3a, a sleeve ring 4a connected by the control screws 5a, 5b to the first tunable rib 2®, as shown in FIG. 2 and 4.

The first rib tunable LC tunable pair of internal ribs 2 ° »1e ^3e comprises a tunable sleeve 62a to the first optical member 61a, which is for the purpose of concentrating the light ray flux slidably mounted in guide bushing 6a. The tunable housing 62a including the optical member 61a is provided on its periphery with two wedge grooves 62a1, 62a2, on whose remote sides the tapered tips 7a1, 7a21 of the setscrews 7a1, 7a2 abut. The set screws 7al,

7a2 go through the threads in the guide sleeve 6a and through the larger holes le1, lc2 at the top of the tunable rib 1c to allow axial movement of the tunable sleeve 62a with the first optical member 61a fixed therein while adjusting its exact position relative to the input connector 31a as shown in FIG. .

The situation of the second tunable rib 1b of the outer pair of tunable ribs 2®, 1b with the clamping sleeve 3b and the output connector 31b, and the second tunable rib 1d of the inner pair of tunable ribs 1c, 21 with the tunable sleeve 62b with the second optical member 61b is mirrored. symmetrical to tunable rib 1a and tunable rib 1c, so that it is not shown in detail in the figures, but is partially evident from FIGS. 1 and 2.

Gear mechanism positioned within the housing, flexible core 2 of the attenuator is formed by three shafts of which the first - supporting shaft 82 »i ^s ° h placed two discs 32a, 32b to the optical filter is provided with circumferential toothing, which in the first disc 32a fits into the toothing a counterwheel 33 disposed on the second tuning shaft 82 for stepping tuning the optical filters, and in the second disk 32b, the gear wheel counterpart 21 located on the third tuning shaft 83 for continuously tuning the optical filter fits. The tuning shafts are provided with scales at the ends projecting from the attenuator housing to read the attenuation rate of the optical filters in the disks 32a, 32b, as shown in Figures 1, 2 and 3.

Since the solution of the measuring optical attenuator according to the invention is essentially aimed at its mechanical configuration, the functional description of the optical system which is the subject of the separate invention is not given below.

Claims (5)

A measuring optical attenuator, comprising an optical system consisting of two discs with optical filters for adjusting the attenuation rate of the transmitted light beam, the input and output connectors, the first and second optical elements, characterized in that the horizontally situated base plate (10) of the flexible core ( 1) an attenuator with a series of vertical ribs (1a to 1f), perpendicular to the axis of the attenuator optical system parallel to the base plate (10) of the flexible core (1), two of which outer form the first bearing rib (le) and the second bearing rib (1f) and four inner ribs provided on opposite sides of the flexible core (1) along one horizontal expansion gap (14, 15) form one outer pair of tunable ribs (1a, 1b), and clamping sleeves (3a, 3b) for receiving an input connector (31b), and a second pair of tunable fins (1c, 1d) for receiving the first optical member (61a) and the second the optical member (61b), wherein all four tunable ribs (1a-1d) are provided at their upper opposite corners with tuning screws (2a-2dl) for vertical, and tuning screws (2a2 to 2d2) for horizontal positioning of the input connector axes ( 31a), an output connector (31b), a first optical member (61a), a second optical member (61b) of the optical system, the optical filter discs (32a, 32b) disposed in the gap (11) between the inner pair of ribs (1c, 1d) ) engage with the gear mechanism counter-wheels (33, 34) mounted on shafts (81, 82, 83) housed in the bushes of the first bearing rib (le) and the second bearing rib (1f), all four tunable ribs (1a to 1). 1d) are provided with holes larger than the diameter of the shafts (81, 82, 83) passing therethrough at the points where the shafts (81, 82, 83) of the transmission mechanism pass through. Measuring optical attenuator according to claim 1, characterized in that the two opposing expansion gaps (14, 15) in the flexible attenuator core (1) terminate in at least all tunable ribs (1a to 1d) with a first relief opening (12) and second relief hole (13) Measuring optical attenuator according to claim 1, characterized in that the first rib (1a) of the outer pair of tunable ribs (1a) is provided with a clamping sleeve (3a) with resilient jaws (3a1) for receiving a guide cylindrical portion of the input connector (31a). without play, wherein a conical ring (4a) is connected to the conical part of the elastic jaws (3a1) connected by the control screws (5a, 5b) to the first tunable rib (1a), while the second outer outer tunable ribs (1b) are provided with similar elements an outlet connector (31b) and is arranged symmetrically to the center plane of the flexible attenuator core (1). Measuring optical attenuator according to Claims 1 to 3, characterized in that the first rib (1c) of the inner pair of tunable ribs (1c, 1d) is provided with a tunable housing (62a) with a first optical member (61a) slidably mounted in the guide sleeve (6a) and is provided with two wedge grooves (62a1, 62a2) on its periphery, on whose remote sides the tapered tips (7a1, 7a21) of the setscrews (7a1, 7a2) pass through the threads in the guide sleeve (6a) and larger the apertures (lcl, le2) at the top of the first of the inner pair of tunable ribs (lc), while the second, inner, tunable rib (ld) is provided with similar elements with a second optical member arranged symmetrically to the center plane of the attenuator core (i). Measuring optical attenuator according to one of Claims 1 to 4, characterized in that the transmission mechanism consists of three shafts, of which on the first support shaft (81) there are two discs (32a, 32b) with optical filters provided with gears on the periphery, which, in the first disc (32a), fits into the gear of the counter wheel (33) located on the second tuning shaft (82) for step-tuning the optical filters and the second disc (32b) fits into the gear teeth of the counter wheel (34) mounted on the third tuning shaft (83) for fine tuning of optical filters.