NL8102017A - ELECTRO-OPTICAL COMPONENT. - Google Patents

Description

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813096 / Ti / vL

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Short designation: Electro-optical component

The invention relates to an opto-electronic coupling element for an optical signal transmission fiber and an electrical signal transmission connection, with. an optoelectronic diode, the photoactive part of which is directed towards the end of the transmission fiber in such a position and at a distance from it that the two elements can mutually influence each other, and wherein the optoelectronic diode can be connected via two connections connected to the electrical signal transmission link.

The transmission of information by optical signals via optical fibers has great technical and economic advantages over the transmission by electric signals via conductive wires.

The processing of this information is practically exclusively in electrical form. It is therefore necessary to convert the optical signals into electrical signals and to convert the electrical signals into optical signals as soon as one wishes to use or transmit information via the optical path.

Such a conversion takes place with the aid of optoelectric devices such as electroluminescent diodes and photodiodes. Such a diode must, on the one hand, be connected to the electronic processing circuit via electrical conductors and, on the other hand, must be positioned very accurately with respect to the ends of the associated optical fiber or optical fibers.

This positioning proves difficult to achieve and maintain in practice without breakage of the 25 "fiber in a certain number of cases, especially when the optoelectronic diode is part of a hybrid chain perpendicular to the plane in which the optical fiber is lying.

The invention provides an optoelectric component which can be formed in a shape similar to that of the classic electronic components, which ensures the positioning of the fiber relative to the diode in a simple and correct manner and which has problems with mounting , occurring when the component with other electronic 8102017 * _ i. , - - .............. - .........-.........

components in a chain must be minimal.

An optoelectronic component for one. optical signal transmission fiber and an electrical signal transmission connection. with an optoelectronic diode, the photoactive part of which is directed towards the end of the transmission fiber in such a position, and at a distance from it that the two elements can influence each other, and wherein the optoelectronic diode through two. connections can be connected to the electrical signal transmission connection, according to the invention characterized by a first, cylindrical electrode, a optoelectronic diode in the voim of a disk provided on one of the two surfaces, a photoactive zone, and an electrical contact zone located outside the photoactive zone, and coupled to the other, and electrically connected to one end of a first cylindrical electrode and further by a tubular member for positioning the transmission fiber with respect to the diode and the first electrode, and a second tubular electrode coaxial with the first electrode and electrically connected to the contact zone connecting the. diode.

The invention is elucidated with reference to the drawing.

Fig. 1 schematically shows the various elements essential to the invention; Fig. 2 is an axial section through this component; FIG. 3 is an enlarged axial section of an embodiment of the invention; Fig. 1+ shows an enlarged axial section of another embodiment.

Fig. 1 shows the elements essential to the invention, namely a first electrode 1, a photoactive diode 2, an optical fiber 3, and the associated protective sleeve Λ. Two elements are not .in, fig. 1 drawn: a positioning element for the optical fiber 3 relative to diode 2 and a second electrode; these elements are shown in more detail in Figs. 2, 3 'and h.

According to the invention, the first electrode 1 is designed such that at the end a light-active diode or one. other suitable optical-electronic element may be provided; this electrode 1 is substantially cylindrical in shape and may consist of a conductive rod, as shown in Fig. 2, or another suitable conductive element in the form of a "T-nail" as in Fig. 3, and ^ shown.

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Diode 2 is either a photo-emitting diode when the signals applied thereto are electrical signals or a light-sensitive diode when the signals to be transmitted are optical signals.

This diode 2 "consists of a disc of semiconductor material, for example a PU'PIT, or PIN" semiconductor photodiode.

One, or both, surface (s) of this disc contain a photoactive zone 7 in the central part and an electrically conductive contact zone 8 outside the photoactive zone 7; this contact zone. forms the first terminal of the diode. 2.

The second surface of the disk is electrically conductive and forms the second terminal of the diode 2; this surface is coupled to the end of the first diode 1 to which it is electrically connected.

A second tubular electrode, not shown, is electrically connected to the contact zone 8 in a manner to be described further.

A positioning element is used directly or indirectly for positioning one end of the optical fiber 3 relative to the photoactive zone 7 of the diode 2, such that each of the two. parts, namely the end and the photoactive zone 7 which can receive light signals, are in the scope of the other. This is achieved in the known manner by placing the end of the optical fiber 3 directly opposite the photoactive surface J.

Figures 2, 3 and k show in more detail different variants to be used with different manufacturing screws as a function of the means used therein.

25. FIG. 2 depicts a first embodiment that achieves a small inter-electrode capacitance and it is possible to insert the optical fiber into the component after mounting it on a printed circuit board. In this variant, the two electrodes, indicated by 1a and 6a, have the same outer diameter. The first electrode 1a is formed by a rod that carries the optoelectronic diode 2a at one end in a manner to be described further; the diode 2a has an electrical contact zone 8a which is preferably annular.

The second electrode 6a is tubular; the inner diameter of the capillary tube formed by it is slightly larger than that of the optical fiber 3a so that this fiber is properly guided and positioned. A first end of the tube, which forms the second electrode 2a, is in contact with the electrical annular contact zone 8a; for example, this first end is 8102017 it.

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soldered or welded to it or in contact with it by contact pressure.

The positioning element 5a is formed by. a tube around the electrode with which the centering is obtained.

The electrodes may consist of an alloy which ensures good adhesion between the glass and the metal, such as, an iron-nickel alloy, and the positioning element 5a consists of a low melting point glass which allows the bond between the two . components. is .insured.

The optical fiber 3a is inserted over the desired length into the second electrode 6a and into this electrode 6a, and. held in the protective sleeve ba. This can be achieved by gluing the end of the optical fiber to the photoactive contact zone with an adhesive that is highly light-conducting, such as a silicone or epoxy adhesive. is in the correct. position with respect to the electrode 6a. . ..

'den by one. sleeve 9a which. the parts have shrunk. or glued.

Fig. 3 shows a second embodiment in which the first electrode 1b has a head portion on which the diode. 2b is positioned in electrical contact with the electrode 1b on its surface in the same manner as described above. This first electrode 1b is. recorded inside. the second electrode 6b formed by a tubular conductor with an inner diameter greater than the maximum diameter of the head sealing the first electrode such that an insulating lead-through element 10b can be formed by pouring the interstices with a suitable synthetic resin or via one or more insulating glass beads. The lead-through element 10b, which is shown in the figure as a block formed from a synthetic resin, also provides. positioning and holding the first electrode in the second. According to a. preferred embodiments are the ends of the electrodes 1b, and 6b in the optoelectronic component, in substantially the self located plane, the first. electrode 1b is longer. than the electrode. 6b and beyond, so that an external chain connection can be formed.

The second electrode 6b is connected to the electrical contact zone 8b of the diode. 2b via a connecting wire 11b soldered at two ends.

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J The optical fiber 3b is positioned with respect to the photoactive zone 7b of the opto-electronic diode 2b by means of - unsigned fasteners such as a casting part and the whole is 81 02 0 1 7 -5 - f Λ on held in place by an adhesive bond 12b formed with a good light conductive adhesive at the end of the optical fiber 3b and the surface of the optoelectronic diode carrying the photoactive zone 7b and the electrical contact zone 8b.

The optical fiber 3b and the protective sleeve kb are aligned with respect to the electrodes 1b and 6b and the synthetic resin block 10b via a synthetic resin casting which forms the positioning element 5b of the optoelectricity formed in this manner. component. In another embodiment, the positioning element 5b is ≤ shaped and may include a portion of the second electrode 6b for obtaining the electrical insulation outside the zone provided for connection to the circuit.

Fig. Ice shows a third embodiment in which no positioning parts or molds are required for mounting and wherein the optical fiber 15 can be inserted into the component after mounting it on the printed wiring.

The component shown in FIG. 1 includes a first electrode 1c, an optoelectronic diode 2c, a second electrode 6c, an insulated lead-through element 10c and a connecting wire 11b, which parts are nearly identical to elements 1b, 2b, 6b, 10b and 11b according to Fig. 3.

The positioning element 5c, on the other hand, is formed by a tubular metal part which is clamped at the location 13c on the second electrode 6c.

This positioning element 5c is tubular and has a first part, the inner diameter of which is slightly larger than the outer diameter of the second electrode 6c on which the element is clamped. The length of the first part is chosen to create a space opposite the surface of the optoelectronic diode 2c carrying the photoactive zone 7c and the contact zone 8c.

A second part of the positioning element 5c has a diameter slightly larger than that. of the protective sleeve Λα of the fiber 3c so that a guide is formed therefor.

In the same manner as in the embodiments described above, the end of the fiber may optionally be glued to the photoactive zone 35.

The second part of the positioning element 5c has an axial recess 14e which is open outwards and whose diameter is slightly 81 0 2 0 1 7 v .................... .........- β- ....... ........... ".............

is greater than the inner diameter of the second part when the. element 5c.

Another 15c is arranged around the protective sleeve kc and fits into the recess 1 Uc; the whole is held by clamping itself.

In the described embodiments, the assembly of the component according to the invention can be carried out. in a circuit, in the same manner as that of a diode or resistor, and through. soldering of. the protruding parts of the electrodes. the. contact jobs with .. using contact strips. In particular, it is possible to position the components that the axis is in a plane parallel to the plane of the circuit to which the electrodes are connected, so that the optical fiber is parallel to the plane of this chain. At one. chain with small dimensions, the optoelectronic components and the chain can be accommodated in the same enclosure which then also comprises a holding and positioning part. for the components, * - [* r i i 8102017

Claims (7)

1. Optoelectronic coupling element for an optical signal transmission fiber and an electrical signal transmission connection, with an optoelectronic diode whose photoactive part is directed towards the end of the transmission fiber in such a position and at a distance from it that the two elements can mutually influence each other, and wherein the optoelectronic diode can be connected via two connections to the electrical signal transmission connection, characterized by a first cylindrical electrode (1), an optoelectronic diode (2) in the form of a slice that on one. of the two surfaces, front view is of a photo-active zone (f) and. an electrical contact zone (8) located outside the photoactive zone (f) 5 and with it. other plane. is coupled and electrically connected to an end of a first cylindrical electrode (1) and further by a tubular element (5) for positioning the transmission fiber with respect to the diode (2) and the first electrode, and a second tubular electrode (6) coaxial with the first electrode (1) and electrically connected to the contact zone (8) carrying the diode (2). 2. Device according to claim 1, characterized in that the two electrodes (1a and 6a) are arranged on either side of the diode (2a) and are held in place by the tubular positioning element (5a) which provides an electrically insulating and forming a sealing base and within which a portion of the electrodes (1a, 6a) and the diode (2a) are located, while the second electrode (6a) is in contact with the contact zone (8a) located on the second surface of the diode, and has an inner diameter slightly larger than the outer diameter of the fiber passing through it (3a) while the transmission fiber sleeve ha is coupled to the second electrode electrode (6a) at that end of this electrode which is not in contact with the diode (2a). Device according to claim 2, characterized in that the two electrodes (1a and 6a) have the same outer diameter and are inserted in a tubular positioning element (5a) made of glass. Device according to claim 3, characterized by a connecting halls (9a) between the sleeve (Ua) of the fiber and the second electrode (6a) coupled to the sleeve and this electrode. Device according to claim 1, characterized in that the first 81 02 0 1 7 -8-to-w / electrode (Tb, 1c) is included in the second, in which it is held by an insulating material lead-through element (10b, 10c) while a jumper (11b, '11c) is electrically connected to the eontet zone (8b, 8c) of the diode (2b, 2c) and closest to this eontet zone (8b, 8c) located end of the second electrode. Device according to claim. 5, characterized in that the lead-through element (10b, 10c) of insulating material is formed by a block of synthetic resin. Device according to claim 55, characterized in that the lead-through element (10b, 10c) is formed of insulating material by a glass bead. Device according to claim 5, characterized in that the end of the transmission fiber (3b) is coupled, and positioned, with respect to the photoactive zone. (7b) of the diode (2b) by means of a drop of optically conductive glue (12), and the tubular positioning element (5b) is formed by a casting of insulating material formed around the fiber (3b) and the protective sleeve. (5b) thereof and. bonded to the ends of the electrodes (1b and 6b) and the spacer (10) positioned adjacent the diode (2b). 9- Device according to claim 5, characterized in that the tubular positioning element (5c) comprises a first part with a diameter slightly larger than the outer diameter of the second electrode (6c) to which this tubular element (5c) is clamped. the first part serving to receive two electrodes (1e, 6c) and the opto-electronic diode (2c), and through a second part with a diameter slightly larger than the outer diameter of the sleeve (i + c) of the fibers passing through and guided (3c). 10. Device according to claim 9, characterized by a spring (15c) wound around the sleeve (Uc) of the optical fiber and partially received in an axial recess (1Ue) of the tubular positioning element (5c) in which the sleeve (Uc) ) and.the spring is held self-clamping. ...... “81 02 01 7 ---------- -----------"