FR2897696A1 - Optoelectronic connector obtaining method, involves mounting optoelectronic light source components which are positioned in elongated manner and are balanced on both sides on four rows in braced insulating rings - Google Patents

Abstract

The method involves mounting optoelectronic light source components (83, 86) which are positioned in an elongated manner and are balanced on both sides on four rows in braced insulating rings. The components are integrated in housings of plastic parts, and are connected by connecting strips (54), where the components include perpendicular electrical contacts. The components are manufactured of a single piece supplying electrical pulses on luminous optoelectronic components. Light transporting pulses on optoelectronic detectors (89, 92) are received at an end of an optical connector (3). An independent claim is also included for a device comprising three sub-assemblies.

Description

DESCRIPTION The originality of the process consists in carrying out a production,

an assembly, a specific assembly (1) comprising optoelectronic components with light sources (83-86-90-93) connected by two or more female connectors (5-6) comprising compulsory links by optical fibers protected by their sheaths; at the other end the information is received by specific optoelectronic detectors equipped (84-87-89-92), balanced on different thicknesses assembled of a printed circuit equipped (11-12) which allows to have buses with information only in bits coming from the appropriate electronic components (8) reference (El) located on this equipped printed circuit (12). Each side of the outer faces of the assembled thicknesses of the printed circuit comprises two minimum rows of optoelectronic components with light sources (83-86-90-93) and optoelectronic detectors (84-87-89-92) which receive the light sources. The optoelectronic components are compulsorily mounted to balance and extended on the printed circuit to inform the other electronic assemblies, each independent. The first printed circuit sub-assembly (13) reference (A) comprises four thin layers (approximately 0.3 mm) all stacked, glued, etched with copper bonds to receive the optoelectronic components with light sources, for the 2nd row (86) as well as for the 4th row (83) and optoelectronic detectors, for the lifter row (92) as well as for the 3rd row (89) (the rows are shown on plan 1) juxtaposed elongated on each side of the different thicknesses assemblies (13) marks (ABC) of the printed circuit (11). The printed circuit comprises on each side of the longitudinal connection strips (16-35-54), having connection contacts which have on one side a perpendicular male plug (22-28-29) and on the other side a socket perpendicular and parallel (22-28-29) (41-42-48) (60-66-67) on the different assembled thicknesses (13) mark (ABC) of the printed circuit. The perpendicular copper contacts are trapped between insulating strips having very precise thicknesses (24-27-31-40-44-47-50) to form sets of longitudinal bars (16-35-54) to be welded (12 ). The thickness of the first printed circuit comprises four layers (13), mark (A) of small thicknesses (approximately 0.3 mm) plus the thicknesses of two assembled sub-assemblies (13) marks (B - C) each of three layers of (approximately 0.3 mm), the whole balanced, stacked, glued, engraved with copper link to receive the elongated juxtaposed optoelectronic components.

Behind the last longitudinal strip (54) of connections are copper pads and holes which can be cut (8) mark (FI) and connected by shielded electric wires (8) mark (FI) to allow the destinations between components to be changed. optoelectronics and electronic components (8) mark (El) on each outer face, which allows modifications of electronic information. A connector (4) comprising an integral part of the printed circuit (12) with a shielded rectangular metal case (4-73) and necessarily rounded ends to functionalize the installation of an O-ring (2) mark (NI) for the sealing. The O-ring (2) mark (Ni) is located in a stamped concavity (73) mark (A) of the male shielded metal housing (73). The fitted printed circuit (10) item (12), comprising longitudinal connection strips (16-35-54) and suitable electronics (8) item (El) must be mounted from the rear of the shielded male rectangular metal box ( 10-73). The two different insulating parts have specific holes (75-76-77-78), have a keying to guide and receive the optoelectronic components with light sources (83-86-90-93) and the optoelectronic detectors (84-87- 89-92). The two specific insulating parts (76-78) fit into the front of the shielded rectangular metal box (71), mark (73), waterproof (71) mark (Ni) and must abut on the stamped perpendicular part comprising a slightly protruding part at the rear of the male shielded rectangular metal housing (72) marked (73). In front of the male metal housing (71), the two different insulating parts (75-76-77-78) are clamped in translation (1) by crimping at the front and by screws (96), with a seal (95) , which makes it possible to have a male fitted sub-assembly (72). The presentation of the fitted printed circuit (12) towards the rear of the shielded fitted rectangular metal case (10) necessarily includes a translational clamping (1) of the printed circuit by shouldered screws (98) with smooth parts with conical ends and seals (97). Opposite the equipped metal case, optoelectronic components with light sources (83-86-90-93) and optoelectronic detectors (84-87-89-92) are positioned and plugged in. The shouldered and smooth screws (98) fit into the necessarily insulating parts of the third and fourth longitudinal bar (54) provided with perpendicular male contacts. The whole assembled comprises an inseparable shielded and waterproof unit (3-4), but can be dismantled if necessary.

Creation of optoelectronic components with light sources (83-86-90-93) comprising different lengths of male contacts with conical ends split vertically over a short length starting from the ends to be elastic. These optoelectronic components are fitted with insulating, perforated, spaced rings (85-88-91-94) having holes for the passage of male contacts. The lengths are different depending on the distances between the longitudinal bars (14-15-16), (33-34-35), (52-53-54), as well as the production of several equipped subassemblies. The housings of the different insulating parts (75-76-77-78), to integrate the optoelectronic components, necessarily include sufficiently large clearances to absorb the tolerances of the various assembled thicknesses of the printed circuit. The insertion of the equipped optoelectronic sub-assemblies (79-80-81-82) comprises insulating, perforated and spaced rings. The optoelectronic assemblies are positioned according to an electrical diagram or a synoptic with markings concerning the appropriate optoelectronic components concerned. The equipped, shielded and sealed modular optoelectronic and electronic assemblies (8-9) are stacked head to tail (7), to produce an electronic computer comprising female connectors made up of fiber optic links (5-6) with very important possibilities of 'evolution according to the different degrees of performance and financing that the client wants to obtain. The optoelectronic and electronic components are supplied by a second shielded and waterproof male connector with copper contacts and shielded electrical wires located near the male optoelectronic connector.

GLOSSARY

Al Optoelectronic components with light sources on all 4 rows; shots (1-4). BI Components for optoelectronic detections on the 4 rows; shots (1-4). Cl Main printed circuit comprising the manufacture of the assembly of three balanced thicknesses; plane (13) reference (A), (13 reference (B), (13) reference (C) .. D1 Different plastic parts symmetrically adjusted in the metal housing of the male connector, plane (71); in relation to the thicknesses of the circuit printed; plan (10). El Electronic components (chips); plans (8). FI Connection modification wires for copper pads and holes for new destinations in relation to suitable electronics; plans (8). G1 Removable part of the female connector with interchangeability of optical fiber links; plans (99-102). H1 Cylindrical sealing gaskets glued to the back of the optical fiber clamping end pieces; plan (99). KI Anti-interference shielding all around of the cover of the electronic components; drawing (1-112). LI Gasket around the periphery of the protective cover of the electronic components; drawing (1-112). MI Several electronic modular assemblies; to compose a flat electronic calculator assembly ( 7-8-9). N1 Flat male metal housing seal (2-71-72). P1 Flat optical fiber (110). R1 Flat shielding joint (112). SI Retaining pin for specific flat plastics (103-104-105-106-107) of the female connector

Claims (9)

1) The mechanical process (10) to obtain optoelectronic connectors (3) mounted on functional printed circuits (11-12) are imperatively connected by optical fiber connectors (5-6-99), the detection is carried out by other connectors (9) comprising optical detectors (89-92). This mechanical process (10) is characterized by mounting optoelectronic components (10-83-86-89-92) imperatively positioned elongated, balanced on both sides on a total of four rows lift 2nd 3rd 4th (1) in insulating rings spaced (85-88- 91-94) and integrated in the housings of the plastic parts (75-76-77-78). The optoelectronic components (83-86-89-92) are electrically connected by specific connection strips (16-35-54), comprising perpendicular electrical contacts, manufactured and machined from a single piece (22-28- 29-41-42-48-60-66-67) feeding the electric pulses controlled by electronics on the luminous optoelectronic components (83-86). The routing of the lighting pulses on optical detectors (89-92) coded by the appropriate electronics are received at the other end of an optoelectronic connector (2-4) on another function printed circuit (8-10 -11-12) or on peripheral electromechanical assemblies. These production methods make it possible to manufacture a shielded and sealed optoelectronic connector (1-4) permanently attached to a functional printed circuit (8-9), this assembly creating independent stackable modules (7) to compose an electronic computer (7). ). 2) Device according to claim N 1 characterized by the production of a printed circuit (13) comprising three assembled sub-assemblies of several bonded layers (13) mark (ABC) which constitute two thicknesses and four stages for assembling connection strips longitudinal females (16-35-54). 3) Device according to claims N 1 and 2 characterized by the specific manufacture of the perpendicular connection contacts (22-28-29), (41-42-48), (60-66-67) comprising female sockets; the parts which are perpendicular to the printed circuit are male contacts of different lengths adapted to each terminal strip which are soldered to the printed circuit (11-12-13). 4) Device according to claim N 1 characterized by a connector (3-4) comprising a rectangular shielded metal male housing equipped (72) with necessarily rounded ends (4) to functionalize the installation of an O-ring (72) mark (NI ) for sealing, the latter being located in a stamped concavity (73) reference (A). 5) Device according to claim N 1 characterized by two metal shielded female connectors (6-99) minimum which during assembly provides a very good seal (72) mark (NI). Optical fibers are used for reading information according to the brightness rates calculated in bits. In the specific insulating strips (103-104-105-106-107) stacked are embedded and integrated shouldered rings (110) integral with their optical fiber, each independent, removable to be interchangeable. 6) Device according to claim Na 1 characterized by two different insulating parts (75-76-77-78) comprising a planar part for uncovering, receiving and guiding the optoelectronic components with light sources (83-86) and the optoelectronic detectors (89 -92). In front of the male metal casing, two different insulating parts (76-78) are clamped in translation (1) by crimping (72) and screws (96) which makes it possible to have a fitted male sub-assembly (72). 7) Device according to claim N 1 characterized in the necessarily insulating parts of the third and fourth longitudinal bar (54) provided with male contacts (60-66-67), shouldered screws with smooth and conical ends (98) clamp the circuit printed equipped in the shielded rectangular metal case (72). 8) Device according to claims N 1-3 characterized by the creation of optoelectronic components with light sources (83-86) comprising different lengths of male contacts with split conical ends (83-86-89-92) vertically on the diameter of ' a short length starting from the ends to be elastic. Perforated insulating rings, braced (85-88-91-94) of different lengths depending on the distances between the longitudinal bars (17-18-19), (36-37-38), (55-56-57) integrate the contacts male optoelectronic components (83-86-89-92). The housings of the insulating parts (76-78), integrate the optoelectronic components (83-86-89-92) which must necessarily include sufficiently large clearances to absorb the tolerances of the various assembled thicknesses of the printed circuit (13) reference (ABC) . The insertion of the equipped optoelectronic sub-assemblies (83-86-89-92) comprising the spacer insulating rings (85-88-91-94) is positioned and embedded according to an electrical diagram or a synoptic with markings concerning the optoelectronic components. adequate concerned. 9) Device according to claim N 1 characterized by several armored and sealed modular assemblies equipped (7-8-9), comprising their specific connections with their specific electronics (8) reference (El), which are stacked head to tail to compose a set upgradeable electronic computer with female connectors with fiber optic bundles (6-99).