RU173132U1 - Optoelectronic module - Google Patents

Abstract

The utility model relates to quantum electronics and can be used to transmit or receive digital data in fiber-optic communication lines for critical purposes under harsh operating conditions, in measuring equipment, in industrial automation systems, etc. The optoelectronic module includes a metal case, inside of which there is a multilayer printed circuit board made of high-frequency material with a working frequency range of no more than 25 GHz or a resistive switching board based on a ceramic substrate with SMD components and integrated circuits installed on it. For connection to external fiber-optic communication lines (FOCL), an optical unit is used, which is a non-separable connection of the optical head with the optical fiber. This optical head 4 is integrated into the design of the housing of the optical module by a non-separable connection, around the circumference of the mating surface. An additional protection against external factors is the placement of the optoelectronic element in a separate housing equipped with a primary focusing lens. The technical result is the creation of an optoelectronic module that allows arbitrary internal layout of data transmission equipment while reducing the overall dimensions of the optoelectronic module, and simplifies the design. 15 s.p. f-ly, 4 ill.

Description

The utility model relates to quantum electronics and can be used to transmit or receive digital data in fiber-optic communication lines for critical purposes under harsh operating conditions, in measuring equipment, in industrial automation systems, etc.

The closest in technical essence and the achieved result is an optical module including an optoelectronic element mounted along the radiation propagation axis, a lens placed at the focal length in front of the working platform of the optoelectronic element, and metal contacts, characterized in that the module is equipped with a metal sealed housing filled with a protective the environment in which the multilayer printed circuit board is mounted on which the electronic components are installed, the multilayer printed circuit board is connected to an optoelectronic element housed in an additional metal sealed housing, the optoelectronic element being an integral part of the optical head integrated into the module body, the optical head has an optical connector at the end and is equipped with a ceramic centralizer (RU, utility model patent No. 155668, class G02B 6 / 42, 2014).

The disadvantages of the known optical module are the appearance of an additional optical interface, which leads to an increase in the level of back reflections in the optical line, the need to place the optical module directly on the front wall of the equipment, and accordingly build the entire configuration of the data transmission equipment. As well as the impossibility of operational maintenance of the optical interface in terms of protection and removal of contaminants, significantly worsening its optical parameters. In addition, the use of an intermediate optical cord dramatically increases the dimensions of the product as part of the equipment (minimum by twice the length of an optical connector of type FC) and complicates the design, reducing its reliability and resistance to special factors.

The technical result, the achievement of which the present technical solution is aimed, is to eliminate these drawbacks and create an optoelectronic module that allows arbitrary internal layout of data transmission equipment. This ensures a reduction in the mass-dimensional characteristics of the optoelectronic module, simplification of the design, improvement of optical parameters and ease of use of the module, and also increases the mechanical strength of the structure and resistance to shock and vibration loads.

The specified technical result is achieved by the fact that in the optoelectronic module including the optoelectronic element mounted along the radiation propagation axis, a lens placed at the focal length in front of the working platform of the optoelectronic element, and metal contacts, the module is equipped with a metal case in which a multilayer printed circuit board is placed, on which is equipped with electronic components, a multilayer printed circuit board is connected to an optoelectronic element located in an additional metal case, wherein the optoelectronic element is an integral part of the optical head integrated into the module housing, according to the utility model, the optical head has a non-separable connection to the optical fiber, while the printed circuit board is made of high-frequency material with a frequency range of not more than 25 GHz, and the printed circuit board includes electronic components of a standard size no more than 2512.

In addition, this technical result is achieved in that the printed circuit board can be made of high-frequency material of ULTRALAM 2000 class.

In addition, the specified technical result is achieved in that the printed circuit board can be made of high-frequency material of class RF4.

In addition, the specified technical result is achieved in that the optical fiber can be placed in a protective sheath.

And also the fact that the non-separable connection can be made by soldering or glue.

In addition, the specified technical result is achieved in that the metal housing can be made airtight.

In addition, the specified technical result is achieved in that the additional metal casing of the optoelectronic element can be sealed.

And also the fact that the metal case can be filled with a protective environment.

In addition, the specified technical result is achieved by the fact that a controlled gas environment is used as a protective medium.

In addition, the specified technical result is achieved by the fact that as a gaseous medium using dried pure nitrogen.

In addition, the specified technical result is achieved by the fact that argon is used as the gaseous medium.

In addition, the specified technical result is achieved in that a mixture of nitrogen and argon in an arbitrary ratio is used as the gaseous medium. In addition, the specified technical result is achieved in that as a gaseous medium using dried atmospheric air.

In addition, the specified technical result is achieved by the fact that freons are used as the gaseous medium.

In addition, the specified technical result is achieved by the fact that a dielectric compound is used as a protective medium.

The optoelectronic module has an optical interface with a pre-installed optical fiber that is not sensitive to microbending - according to the international classification ITU-T G.652 or G.657. This optical fiber can be placed in various protective shells - Buffer 0.9 mm, Simplex 2.0 mm, Simplex 3.0 mm, or a shell with metal armor, which have various combinations of strength and flexibility depending on operating requirements.

The optical cable can be terminated with any optical connector or can be connected to external communication lines by welding optical fiber.

Due to the use of micro-components for alignment and fastening of the optical cable, the dimensions of the optical module itself can be significantly reduced - by no less than 15%.

By reducing the size of the optical module, improving the optical and electrical parameters and improving coordination with external communication lines, the maximum data transfer rate is increased to 11 Gbit / s.

By reducing the dimensions of the module and the mass of the docking station with the external optical communication line, the mechanical strength of the structure and resistance to shock-vibration loads are increased.

In FIG. 1 shows a general view of an optical module;

in FIG. 2 shows a transmitting optical head;

in FIG. 3 shows a receiving optical head;

in FIG. 4 shows a glass-metal base.

The optoelectronic module includes a metal housing 1, which can be sealed, made of corrosion-resistant metal, for example, structural steel 08X18H9 GOST 5632-72 or similar material with a thickness of 0.1 to 10 mm. Sealing is achieved through the use of pulsed laser welding in a shielding gas medium to connect all parts of the housing.

Inside the housing 1 there is a multilayer printed circuit board 2 (MPP - a printed circuit board consisting of alternating conductive and non-conductive layers having a given pattern of each layer, connected in accordance with the circuit diagram of the printing unit) of high-frequency material such as ULTRALAM 2000, RF4 or similar with a range of working frequencies of no more than 25 GHz, or a resistive switching board based on a ceramic substrate with SMD components and integrated circuits 3 installed on it.

For connection to external fiber-optic communication lines (FOCL), an optical unit is used, which is an inseparable connection of the optical head 4 with the optical fiber 5, equipped with any connector compatible with standard optical connectors with UPC or APC polishing, or having a piece of optical fiber for connection by welding. This optical head 4 is integrated into the design of the housing 1 of the optical module by non-separable connection, for example, by laser welding, soldering or adhesive bonding, around the circumference of the mating surface 6.

An additional protection against external factors is the placement of the optoelectronic element 7 (laser radiation source or photodiode) in a separate housing 8, equipped with a primary focusing lens 9. The housing 8 can be sealed.

The reproducibility of the parameters of the optical interface is achieved by the fact that in the design of the optical unit, consisting of a supporting body 10, the housing 8 of the optoelectronic element 7, a laser radiation source or a photodiode, on which the primary focusing lens 9 is installed, with the optical fiber end in focus, is fixed by laser welding 5 having angular polishing or spherical polishing. The fixation of the optical fiber 5 is carried out using a special solder or glue inside the ceramic ferrule 11, to protect the optical fiber 5, a protective sheath 12 is used with a diameter of 0.9 mm, 2.0 mm, 3.0 mm or another diameter, for fixing which a sleeve 13 is used or 18, which may be filled with an adhesive compound.

The use of a metal-glass base 19 with a normalized wave impedance of electrical leads made of 29NK alloy according to GOST 10994-74 or its analogue, with wire leads 20 installed in glass insulators 21, allows to achieve high coordination in frequency characteristics with external communication lines, from sources and to digital receivers, as well as its compatibility with other electronic components for surface mounting.

Inside the housing 1 of the optical module can be placed under pressure up to 4.5 atm. (441.3 kPa) controlled gas environment - dried pure nitrogen or argon, a mixture of them in an arbitrary ratio, or dried atmospheric air, or freon such as trifluoriodomethane. Dielectric compound pouring is invariantly applied, which allows to improve cooling of internal electronic components and increase resistance to high / low atmospheric pressure, including space vacuum, and also prevents moisture, oxygen and other oxidizing agents from getting inside, eliminates the emission of harmful impurities during operation as a part of hermetic modules of electronic equipment .

The optoelectronic module operates as follows.

When converting an electronic signal into an optical initial electronic signal through the external electrical terminals 20 of the base 19 of the housing 1, it enters the matching circuit with the external communication line (buffer device included in the microcircuit 3), then into the pump current modulation system (also included in the microcircuit 3 ), a laser diode or LED, which is part of the optoelectronic element 7. At the same time, the supply voltage enters the reference voltage source and from it into the modulation system and other components topics that are part of the microcircuit 3. To ensure the stability of the output optical power in the module, a feedback system is used, implemented as a feedback photodiode of the optoelectronic element 7 installed directly in the housing 8, and a pump current stabilization module, which is part of the microcircuit 3. Stabilized the pump current through the modulator, which is part of the chip 3, is fed to a laser diode or LED, which are part of the optoelectronic element 7, causing the generation of optical radiation, opt whose apparent power is proportional to the flowing current. Thus, an amplitude-modulated electrical signal corresponds to an output optical signal modulated in intensity (output optical power). As additional systems in the design of the optoelectronic module, switching elements of the pump current and the operability control of individual circuit components can be installed. To connect to an external fiber-optic communication line, a patch cord is used, consisting of a segment of optical fiber 5, which can be placed in a protective sheath 12. Optical fiber 5 at the point of connection with the fiber optic link can be equipped with any optical connector or can be stripped for welding.

The design of the pigmented optical assembly of the transmitting optical module consists of the optoelectronic element 7 itself, having its own housing 8, placed in the base housing 10, to which the connecting sleeve 17 is mounted by welding. To align the end of the optical fiber, quotation sleeves 15, 13, 16 and 14 are used. Additionally, the sleeves 13 and 14 are clamps of the optical insulator 11, into which the optical fiber 5 is glued.

When converting an optical signal into an electrical source optical signal from an external fiber-optic communication line through a patch cord, consisting of a piece of optical fiber 5, which can be placed in a protective sheath 12, and connected to the fiber optic splice point by any optical connector or welded joint, in the optoelectronic module 7, placed in the housing 8, in which the primary focusing optics 9 is integrated. For alignment with the optical fiber, an external housing 10 and a ceramic ferula 11, in which an optical fiber 5 is installed. The optical fiber can be placed in a protective sheath 12, which can be fixed with an adhesive compound inside the sleeve 13. The end of the ferrule 11 with glued fiber facing the optoelectronic module 7 is polished according to the UPC or APC class. To connect to the housing 1 of the receiving optical module, a sleeve 17 having a mounting plane 6 for laser welding is mounted on the housing of the photodiode head.

Optical radiation enters the photodiode, which is part of the optoelectronic element 7 and is switched on according to the forward bias circuit. The photocurrent generated by the action of optical radiation on a photodiode first goes to a transimpedance amplifier, then to a selective filter, then to a limiter amplifier and then to a level matching device, which are part of microcircuit 3. From the output of the level matching device, the electronic signal is fed through external electrical terminals 20 of the base 19 in line with the consumer. A voltage source is used to power all systems and components. The operation of the photodetection system is regulated by an automatic gain control system that receives data from a transimpedance amplifier, at the same time these data are fed to a level detector and then to a comparator. The output signal of the comparator generates a signal corresponding to the photocurrent to the minimum specified value, proportional to the input optical power, sufficient for reliable conversion of the optical signal into electrical, all these components are part of microcircuit 3 and are located on MPP 2. Elements can be installed as additional systems in the design of the optoelectronic module switching output electronic signals and monitoring the health of individual components of the circuit.

Thus, the proposed optoelectronic module is highly reliable due to the high resistance to external electromagnetic fields, including the effects of ionizing radiation and radiation in open space, an extended life of up to 25 years with an active life of 15 years, provides a high degree of universality of connection to any type fiber optic communication lines (FOCL) based on standard optical connectors or optical fiber welding and lack of necessary the ability to use external systems and components to connect to standard sources and receivers of digital data.

The high reliability of the proposed optoelectronic module allows you to operate the product in the temperature range from minus -60 to + 85 ° C in combination with an impact load of up to 1000g and broadband vibration of up to 2500 Hz at 10g acceleration, a high level of external electromagnetic fields, including ionizing radiation and open cosmic radiation space.

Claims (16)

1. An optoelectronic module, including an optoelectronic element mounted along the axis of radiation propagation, a lens placed at the focal length in front of the working platform of the optoelectronic element, and metal contacts, the module is equipped with a metal case in which a multilayer printed circuit board on which electronic components are mounted is laminated the printed circuit board is connected to the optoelectronic element housed in an additional metal housing, while the optoelectronic element is a composite part of the optical head integrated into the module housing, characterized in that the optical head has a non-separable connection to the optical fiber, while the printed circuit board is made of high-frequency material with an operating frequency range of not more than 25 GHz, and the printed circuit board includes electronic components of a standard size of not more than 2512 . 2. The optoelectronic module according to claim 1, characterized in that the printed circuit board is made of high-frequency material of ULTRALAM 2000 class. 3. The optoelectronic module according to claim 1, characterized in that the printed circuit board is made of high-frequency material of class RF4. 4. The optoelectronic module according to claim 1, characterized in that the optical fiber is placed in a protective sheath. 5. The optoelectronic module according to claim 1, characterized in that the non-separable connection is made by soldering. 6. The optoelectronic module according to claim 1, characterized in that the non-separable connection is made by glue. 7. The optoelectronic module according to claim 1, characterized in that the metal housing is sealed. 8. The optoelectronic module according to claim 1, characterized in that the additional metal housing of the optoelectronic element is sealed. 9. The optoelectronic module according to claim 1, characterized in that the metal housing is filled with a protective medium. 10. The optoelectronic module according to claim 9, characterized in that a controlled gas medium is used as the protective medium. 11. The optoelectronic module according to claim 10, characterized in that dried pure nitrogen is used as the gaseous medium. 12. The optoelectronic module according to claim 10, characterized in that argon is used as the gaseous medium. 13. The optoelectronic module according to claim 10, characterized in that a mixture of nitrogen and argon in an arbitrary ratio is used as the gaseous medium. 14. The optoelectronic module according to claim 10, characterized in that dried air is used as the gaseous medium. 15. The optoelectronic module according to claim 10, characterized in that freons are used as a gaseous medium. 16. The optoelectronic module according to claim 9, characterized in that a dielectric compound is used as a protective medium.

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