CN115171972A - 1.8-4.2mm flat photoelectric hybrid cable assembly applied to F5G system - Google Patents

Abstract

The invention discloses a 1.8-4.2mm flat photoelectric hybrid cable component applied to an F5G system, which comprises a flat photoelectric hybrid cable and a photoelectric connector, wherein the flat photoelectric hybrid cable is connected with the photoelectric connector; the size of the flat photoelectric hybrid cable is 1.8 multiplied by 4.2mm, and the size of the photoelectric connector is 32 multiplied by 6 multiplied by 6.7mm; two power lines are respectively arranged on two sides of the flat photoelectric hybrid cable in parallel, a positive power line is arranged on one side, a negative power line is arranged on the other side, an outer sheath is arranged on the outer layer of the flat photoelectric hybrid cable, and a circular gap is formed between the positive power line and the negative power line. The invention has small outer diameter, light weight, small occupied space, bending resistance and convenient construction, provides long-term stable high bandwidth and low time delay connection for the coiling installation of the corollary equipment, and is combined with the 5G wireless of the corollary equipment; the tail sleeve is resistant to bending, so that long-term stable photoelectric synchronous transmission can be provided; the welding spot of the power line inside the photoelectric connector and the gap are filled with injection molding materials, so that the photoelectric connector is excellent in insulating property and strong in tensile property, and meanwhile, the optical fiber can be better protected.

Description

1.8-4.2mm flat photoelectric hybrid cable assembly applied to F5G system

Technical Field

The invention relates to the technical field of communication, in particular to a 1.8-4.2mm flat type photoelectric hybrid cable component applied to an F5G system.

Background

F5G is a fifth generation fixed communication network, defined by the European Telecommunications Standards Institute (ETSI), and is dedicated to moving from fiber to the home towards the optical community. The F5G is based on an optical fiber communication technology, has the characteristics of ultra-large bandwidth, all-optical connection, low time delay, safety, stability and the like, supports kilomega families, giga buildings and T-level parks, and enables users to experience high-quality networks. The F5G can be comprehensively applied to four scenes, namely 'full-optical transmission, full-optical access, a full-optical data center and a full-optical park', and the F5G and the 5G can be expected to fully utilize the mass bandwidth of an optical network and the mobility of a wireless network and combine the mass connection advantages of the two, thereby jointly promoting the prosperity of the gigabit broadband industry, constructing the connection foundation of thousands of industries and constructing the intelligent world of interconnection of everything.

The existing mixed cable assembly has poor stability, weak tensile strength, heavy weight and space occupation.

Disclosure of Invention

The invention aims to provide a 1.8-4.2mm flat photoelectric hybrid cable component applied to an F5G system, so as to solve the problems of poor stability, low tensile strength, heavy weight and space occupation in the background technology.

In order to achieve the purpose, the invention adopts the following technical scheme: a1.8-4.2 mm flat photoelectric hybrid cable component applied to an F5G system comprises a flat photoelectric hybrid cable 1 and a photoelectric connector 2, wherein the flat photoelectric hybrid cable 1 is connected with the photoelectric connector 2; the size of the flat photoelectric hybrid cable 1 is 1.8 multiplied by 4.2mm, and the size of the photoelectric connector 2 is 32 multiplied by 6 multiplied by 6.7mm; the flat type photoelectric hybrid cable is characterized in that two sides of the flat type photoelectric hybrid cable 1 are respectively provided with a power line in parallel, one side of the flat type photoelectric hybrid cable is provided with a positive power line 11, the other side of the flat type photoelectric hybrid cable is provided with a negative power line 12, an outer layer of the flat type photoelectric hybrid cable 1 is provided with an outer sheath 14, and a circular gap 13 is arranged between the positive power line 11 and the negative power line 12.

The positive power line 11 is red, the negative power line 12 is blue, the conductors of the positive power line 11 and the negative power line 12 are composed of stranded bare copper wires, and the insulating layer is made of LSZH material; the diameter of the circular gap 13 is 1.3mm, aramid yarn is filled in the circular gap 13 and a tightly-packed optical cable with the diameter of 0.6mm is wrapped, and the outer sheath 14 is made of a white LZSH material with a low friction coefficient and meets the ROHS2.0 environmental protection requirement. The working temperature is-20 ℃ to 80 ℃, the highest working voltage and current are 56V/0.5A, and the minimum static bending radius can reach 42mm.

Photoelectric connector 2 includes preceding shell 21, backshell 22, conductor base 23, screw ring 24, pottery lock pin 25, spring 26 and the tail cover 27 of moulding plastics, preceding shell 21 downside is equipped with guide slot 211, conductor base 23 install in the guide slot 211, pottery lock pin 25 model is 2.5UPC.

The assembling method of the photoelectric connector 2 comprises the following steps:

the front shell 21 is preassembled: installing the conductor base 23 into the guide groove 211 on the lower side of the front shell 21, pushing to the top to ensure that the metal contacts on the two sides of the front end of the conductor base 23 are installed in place;

the rear shell 22 is preassembled: preparing a section of PBT hard tube to stretch into the rear shell 22 and fixing the PBT hard tube by using glue, screwing the thread ring 24 after the glue is solidified, stripping the flat photoelectric hybrid cable 1 to remove the skin and aramid fiber of the outer sheath 14, reversely folding the anode power line 11 and the cathode power line 12 and fixing the anode power line and the cathode power line by using an adhesive tape, penetrating the assembled rear shell 22 into a tight-coated optical cable with the diameter of 0.6mm, and completely penetrating the PBT hard tube into the outer sheath. Stripping a sheath with the diameter of 0.6mm and a coating layer of the tightly packaged optical cable, penetrating the spring 26 and the ceramic ferrule 25 injected with the glue, and placing the tightly packaged optical cable in a curing furnace for curing;

the tail handle of the cured ferrule 25 needs to be spaced from the front end of the rear shell 22 to prevent glue from adhering, the ferrule 25 is installed in the front shell 21, the front shell 21 and the rear shell 22 are assembled by using a combination tool, and the notch of the front shell 21 and the protrusion of the rear shell 22 are completely clamped. Two teeth are reserved in the thread ring 24 of the rear shell 22, and an inner cavity of the front shell 21 is reserved to ensure that the later-stage tail sleeve injection molding filling forms an inverted buckle, so that the tensile resistance is increased;

and reserving enough length for stripping an insulating layer of 4mm on the positive power line 11 and the negative power line 12, welding the insulating layers on a metal sheet welding area at the rear end of the conductor base 23, wherein the connection sequence of the power lines at the two ends is reverse, and forming a direct current power line to provide stable power supply. The exposed part after welding is coated by a heat-shrinkable tube, and the coating length needs to be lapped to the thread ring 24 and part of the outer sheath 14, so that the damage to the optical fiber caused by injection molding and glue punching is prevented;

the tail sleeve injection molding material is made of white TPEE material, and meets the ROHS2.0 environmental protection requirement. The tail sleeve is integrally formed by injection molding, the welding spots and the gaps of the power line inside the photoelectric connector are filled with injection molding materials, the insulation performance is excellent, the tensile property of the connector reaches 70N, and meanwhile, the optical fiber is better protected. The injection structure design of the tail sleeve ensures that the cable is not cracked and has no short circuit or open circuit when being repeatedly bent for more than 50 times under the condition of loading 200g of heavy objects at +/-90 degrees, the variation of optical indexes is less than or equal to 0.5dB, the optical performance of the photoelectric connector is small in insertion loss fluctuation due to the adoption of a UPC grinding process, the insertion loss is less than or equal to 0.5dB, the return loss is more than or equal to 52dB, and full-optical transmission and full-optical access are realized by matching with matched equipment.

Compared with the prior art, the invention has the following beneficial effects:

the invention has small outer diameter, light weight, small occupied space, bending resistance, convenient construction and environment-friendly material; the long-term stable high-bandwidth and low-delay connection is provided for the matched equipment after being coiled and installed, and the high-bandwidth and low-delay connection is combined with the 5G wireless connection of the matched equipment; the tail sleeve is resistant to bending, so that long-term stable photoelectric synchronous transmission can be provided; the photoelectric connector has the advantages that the welding spots and the gaps of the power line inside the photoelectric connector are filled with the injection molding material, so that the insulating property is excellent, the tensile strength is high, and meanwhile, the optical fiber can be better protected.

Drawings

FIG. 1 is a schematic view of a flat hybrid optical/electrical cable according to the present invention;

FIG. 2 is a schematic view of an optoelectronic connector according to the present invention;

FIG. 3 is a schematic view of a heat shrinkable tube according to the present invention;

FIG. 4 is a schematic view of a conductor mount of the present invention;

FIG. 5 is a schematic view of a rear housing of the present invention;

FIG. 6 is a schematic cross-sectional view of a rear housing of the present invention;

fig. 7 is a schematic view of the front housing of the present invention.

In the figure: 1. a flat type photoelectric hybrid cable; 11. a positive power supply line; 12. a negative power supply line; 13. a circular void; 14. An outer sheath; 2. a photoelectric connector; 21. a front housing; 211. a guide groove; 22. a rear housing; 23. a conductor mount; 24. a thread ring; 25. a ceramic ferrule; 26. a spring; 27. and (4) injection molding of the tail sleeve.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is to be understood that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work based on the embodiments of the present invention belong to the scope of the present invention.

As shown in fig. 1 to 7, a 1.8-4.2mm flat optical-electrical hybrid cable assembly applied in an F5G system includes a flat optical-electrical hybrid cable 1 and an optical-electrical connector 2, where the flat optical-electrical hybrid cable 1 is connected to the optical-electrical connector 2; the size of the flat photoelectric hybrid cable 1 is 1.8 multiplied by 4.2mm, and the size of the photoelectric connector 2 is 32 multiplied by 6 multiplied by 6.7mm; the flat type photoelectric hybrid cable is characterized in that two sides of the flat type photoelectric hybrid cable 1 are respectively provided with a power line in parallel, one side of the flat type photoelectric hybrid cable is provided with a positive power line 11, the other side of the flat type photoelectric hybrid cable is provided with a negative power line 12, an outer layer of the flat type photoelectric hybrid cable 1 is provided with an outer sheath 14, and a circular gap 13 is arranged between the positive power line 11 and the negative power line 12.

The positive power line 11 is red, the negative power line 12 is blue, the conductors of the positive power line 11 and the negative power line 12 are composed of stranded bare copper wires, and the insulating layer is made of LSZH material; the diameter of the circular gap 13 is 1.3mm, aramid yarns are filled in the circular gap 13 and wrap a tightly-packed optical cable with the diameter of 0.6mm, and the outer sheath 14 is made of a white LZSH material with a low friction coefficient.

Photoelectric connector 2 includes preceding shell 21, backshell 22, conductor base 23, screw thread circle 24, ceramic lock pin 25, spring 26 and the tail cover 27 of moulding plastics, preceding shell 21 downside is equipped with guide slot 211, conductor base 23 install in the guide slot 211.

As shown in fig. 2 to fig. 6, the assembly method of the photoelectric connector 2 includes:

the front shell 21 is preassembled: installing the conductor base 23 into the guide groove 211 on the lower side of the front shell 21, pushing to the top to ensure that the metal contacts on the two sides of the front end of the conductor base 23 are installed in place;

the rear shell 22 is preassembled: preparing a section of PBT hard tube to stretch into the rear shell 22 and fixing the PBT hard tube by using glue, screwing the thread ring 24 after the glue is solidified, stripping the flat photoelectric hybrid cable 1 to remove the skin and aramid fiber of the outer sheath 14, reversely folding the anode power line 11 and the cathode power line 12 and fixing the anode power line and the cathode power line by using an adhesive tape, penetrating the assembled rear shell 22 into a tight-coated optical cable with the diameter of 0.6mm, and completely penetrating the PBT hard tube into the outer sheath. Stripping a sheath with the diameter of 0.6mm and a coating layer of the tightly packaged optical cable, penetrating the spring 26 and the ceramic ferrule 25 injected with the glue, and placing the tightly packaged optical cable in a curing furnace for curing;

the tail handle of the cured ferrule 25 needs to be spaced from the front end of the rear shell 22 to prevent glue from adhering, the ferrule 25 is installed in the front shell 21, the front shell 21 and the rear shell 22 are assembled by using a combination tool, and the notch of the front shell 21 and the protrusion of the rear shell 22 are completely clamped. Two teeth are reserved in the thread ring 24 of the rear shell 22, and an inner cavity of the front shell 21 is reserved to ensure that the later-stage tail sleeve injection molding filling forms an inverted buckle, so that the tensile resistance is increased;

and reserving enough length for stripping an insulating layer of 4mm on the positive power line 11 and the negative power line 12, welding the insulating layers on a metal sheet welding area at the rear end of the conductor base 23, wherein the connection sequence of the power lines at the two ends is reverse, and forming a direct current power line to provide stable power supply. And covering the exposed part after welding by using a heat shrink tube, wherein the covering length needs to be lapped on the thread ring 24 and part of the outer sheath 14, so as to prevent the injection molding glue punching from damaging the optical fiber.

The foregoing shows and describes the general principles, principal features, and advantages of the invention. It should be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and the above-described embodiments and descriptions are only preferred examples of the invention and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. A1.8-4.2 mm flat type photoelectric hybrid cable assembly applied to an F5G system is characterized by comprising a flat type photoelectric hybrid cable (1) and a photoelectric connector (2), wherein the flat type photoelectric hybrid cable (1) is connected with the photoelectric connector (2); the size of the flat photoelectric hybrid cable (1) is 1.8 multiplied by 4.2mm, and the size of the photoelectric connector (2) is 32 multiplied by 6 multiplied by 6.7mm; the flat type photoelectric hybrid cable is characterized in that two power lines are respectively arranged on two sides of the flat type photoelectric hybrid cable (1) in parallel, one power line is a positive power line (11), the other power line is a negative power line (12), an outer sheath (14) is arranged on the outer layer of the flat type photoelectric hybrid cable (1), and a circular gap (13) is formed between the positive power line (11) and the negative power line (12).

2. The 1.8-4.2mm flat type photoelectric hybrid cable assembly applied in the F5G system is characterized in that the positive power line (11) is red, the negative power line (12) is blue, the conductors of the positive power line (11) and the negative power line (12) are composed of stranded bare copper wires, and the insulating layer is made of LSZH material; the diameter of the circular gap (13) is 1.3mm, aramid yarns are filled in the circular gap (13) and wrap a phi 0.6mm tightly-wrapped optical cable, and the outer sheath (14) is made of a white LZSH material with a low friction coefficient.

3. The 1.8-4.2mm flat type optical-electrical hybrid cable assembly applied in the F5G system according to claim 1, wherein the optical-electrical connector (2) comprises a front shell (21), a rear shell (22), a conductor base (23), a threaded ring (24), a ferrule (25), a spring (26) and an injection molding tail sleeve (27), a guide groove (211) is formed in the lower side of the front shell (21), and the conductor base (23) is installed in the guide groove (211).

4. The 1.8-4.2mm flat type optical-electrical hybrid cable assembly applied in F5G system according to claim 3, wherein the assembling method of the optical-electrical connector (2) is as follows:

the front shell (21) is preassembled: the conductor base (23) is installed into the guide groove (211) on the lower side of the front shell (21) and pushed to the top to ensure that metal contacts on two sides of the front end of the conductor base (23) are installed in place;

the rear shell (22) is preassembled: preparing a section of PBT hard tube to stretch into the rear shell (22) and fixing the PBT hard tube by using glue, screwing the thread ring (24) after the glue is solidified, stripping the flat photoelectric hybrid cable (1) to remove the skin and aramid fiber of the outer sheath (14), reversely folding the anode power line (11) and the cathode power line (12) and fixing the anode power line and the cathode power line by using an adhesive tape, penetrating the assembled rear shell (22) into a tight-packaged optical cable with the diameter of 0.6mm, and completely penetrating the PBT hard tube into the sheath. Stripping a sheath with the diameter of 0.6mm and a coating layer of the tightly packaged optical cable, penetrating the spring 26 and the ceramic ferrule (25) injected with the glue, and placing the tightly packaged optical cable in a curing furnace for curing;

and the tail handle of the cured ceramic ferrule (25) needs to be spaced from the front end of the rear shell (22) to prevent glue adhesion, the ceramic ferrule (25) is installed in the front shell (21), the front shell (21) and the rear shell (22) are assembled by using a combined tool, and the notch of the front shell (21) is completely clamped with the protrusion of the rear shell (22). Two teeth are reserved in the thread ring (24) of the rear shell (22), and an inner cavity of the front shell (21) is reserved to ensure that the tail sleeve is injection-molded and filled to form an inverted buckle in the later period, so that the tensile property is increased;

and reserving enough length for stripping an insulating layer of 4mm on the positive power line (11) and the negative power line (12), welding the insulating layers on a metal sheet welding area at the rear end of the conductor base (23), wherein the connection sequence of the power lines at the two ends is reverse, and forming a direct current power line to provide stable power supply. And covering the exposed part after welding by using a heat-shrinkable tube, wherein the covering length of the heat-shrinkable tube needs to be lapped to the thread ring (24) and part of the outer sheath (14), so that the damage to the optical fiber caused by injection molding and glue punching is prevented.

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