CN105137545A - Optical cable assembly - Google Patents

Abstract

The invention relates to an optical cable assembly, and the assembly comprises an optical fiber connector and an optical fiber back plate. A first optical fiber back plate unit of the optical fiber back plate comprises a first back plate base body, and the first back plate base body of the first optical fiber back plate unit is provided with a first back plate through groove. A second back plate base body of a second back plate unit of the optical fiber back plate comprises a second back plate right segment which is located above the first back plate base body and is used for the arrangement of an outgoing wire end of the second optical fiber, a second back plate left segment which is located below the first back plate base body and is used for the arrangement of an incoming wire end of the second optical fiber, and a second back plate central segment which is connected between the second back plate left segment and the second back plate right segment. The second back plate central segment passes through the first back plate through groove, and an incoming wire end of a second optical fiber is located below an incoming wire end of a first optical fiber belt. An outgoing wire end of the second optical fiber is located above an outgoing wire end of the first optical fiber belt. The assembly provided by the invention can achieve that the optical fiber among the optical fiber back plate units can be intersected with each other vertically.

Description

A kind of cable assembly

Technical field

The present invention relates to the cable assembly in optical signal transmission field.

Background technology

Along with the development of infotech, Optical Fiber Transmission is applied in increasing communication system, in order to realize the high density transmission of light signal, comprise the fibre ribbon application of multifiber and give birth to, traditional fibre ribbon is flat belt-like form, and it is formed, during use side by side by the bare fibre of 4,8,12,24 or other quantity, the connector of special type is made, with communicating optical signals at the input end of optical fiber and the output terminal of optical fiber.During the optical fiber transmission of signal of this kind of form, the signal of its one end and the other end is one to one, signal cannot be delivered to an other fibre ribbon from a fibre ribbon, along with the treatment capacity of data of information system is increasing, signal cross between fibre ribbon and fibre ribbon is inevitable, existing use arranges optical fiber backboard optical fiber backboard disclosed in US Patent No. 6744956 of cross light fibre ribbons, this optical fiber backboard comprises the first optical fiber backboard unit and the second optical fiber backboard unit of mounted on top, second optical fiber backboard unit comprises the first backplane substrate, second optical fiber backboard unit comprises the second backplane substrate, first backplane substrate is provided with two the first fibre ribbons, second backplane substrate is provided with two the second fibre ribbons, the optical fiber lead-in wire terminal of two the first fibre ribbons is between left and right every setting, the optical fiber lead-in wire terminal of two the second fibre ribbons is between left and right every setting, the optical fiber lead-in wire terminal of two the first fibre ribbons is in the top of the optical fiber lead-in wire terminal of two the second fibre ribbons, first, the fibre ribbon that after optical fiber leading-out terminal intersection restructuring in second fibre ribbon, formation four is new, to complete the Cross transfer of fiber-optic signal, the optical fiber leading-out terminal of the first fibre ribbon is in the top of the optical fiber leading-out terminal of the second fibre ribbon.Existing this optical fiber backboard Problems existing is: the intersection that can only realize horizontal direction between the optical fiber between each optical fiber backboard unit, and the intersection of above-below direction can not be realized, namely the optical fiber lead-in wire terminal of the first fibre ribbon is in the top of the optical fiber lead-in wire terminal of the second fibre ribbon, the optical fiber leading-out terminal of the first fibre ribbon is in the top of the optical fiber leading-out terminal of the second fibre ribbon, along with the high speed development of communication facilities, the application of many rows high-density optical fiber connector is more and more extensive, when connecting alternately appears in the signal between row and row of many row's joints of optical fibre, this kind of optical fiber backboard just cannot solve this problem.

Summary of the invention

The object of the present invention is to provide a kind of cable assembly that can realize the optical fiber between optical fiber backboard unit and can intersect in the vertical direction.

In order to solve the problem, in the present invention, the technical scheme of cable assembly is:

Cable assembly, comprise the joints of optical fibre and optical fiber backboard, optical fiber backboard comprises the first optical fiber backboard unit and the second optical fiber backboard unit, first optical fiber backboard unit comprises the first backplane substrate, first backplane substrate is provided with the first fibre ribbon be connected with the described joints of optical fibre for carrying light signal along the longitudinal direction, second optical fiber backboard unit comprises the second backplane substrate, second backplane substrate is provided with the second fibre ribbon be connected with the described joints of optical fibre, first backplane substrate is provided with the first backboard running through described first backplane substrate along the first backplane substrate thickness of slab direction and wears groove, section on the right side of the second backboard that the leading-out terminal that second backplane substrate comprises confession second optical fiber be in above described first backplane substrate is arranged, section and the second backboard interlude of being connected on the left of described second backboard on the right side of section and the second backboard between section on the left of the second backboard that the lead-in wire terminal being in confession second optical fiber below described first backplane substrate is arranged, second backboard interlude is arranged in described first backboard and wears in groove, the lead-in wire terminal of the second fibre ribbon is positioned at below the lead-in wire terminal of the first fibre ribbon, the leading-out terminal of the second optical fiber is positioned at above the leading-out terminal of the first fibre ribbon.

Described second backplane substrate is made up of flexible material.

First optical fiber is with at least two, and the optical fiber in each first fibre ribbon intersects restructuring on the right side that groove worn by described first backboard, and the first backboard is worn centre that groove is in the first backplane substrate and to be kept left position.

The left end that groove worn by first backboard extends on the left surface of described first backplane substrate, second backplane substrate is provided with the second backboard that the right-hand member that runs through described second backplane substrate along the second backplane substrate thickness of slab direction extends on the right flank of described second backplane substrate and wears groove, section on the right side of the first backboard that the leading-out terminal that first backplane substrate comprises confession second fibre ribbon be positioned on the right side of described second backboard below section is arranged, section and the first backboard interlude of being connected on the left of described first backboard on the right side of section and the first backboard between section on the left of the first backboard that the lead-in wire terminal of confession second fibre ribbon on the left of described second backboard above section is arranged, first backboard interlude is arranged in described second backboard and wears in groove.

Described first backplane substrate is made up of flexible material.

Beneficial effect of the present invention is: wear groove by arranging the first backboard in the first backplane substrate, during use, second backboard interlude is worn in groove to pass thus realize section on the right side of the second backboard by the first backboard and is in the top of the first backplane substrate, on the left of second backboard, section is in the below of the first backplane substrate, the lead-in wire terminal being arranged at the second fibre ribbon of section on the left of the second backboard so just can be in the below of the first fibre ribbon, the leading-out terminal being arranged at the second fibre ribbon of section on the right side of the second backboard just can be in the top of the second fibre ribbon, thus the optical fiber mutual intersection in the vertical direction realized between optical fiber backboard unit, thus be applicable to use in the environment when appearance of signal between row and row of arranging the joints of optical fibre connects alternately.

Accompanying drawing explanation

Fig. 1 is the using state figure of the joints of optical fibre and adapts optical connector in the present invention;

Structural representation when Fig. 2 is the joints of optical fibre and the grafting of adapts optical connector in Fig. 1;

Fig. 3 is the A place enlarged drawing of Fig. 2;

Fig. 4 be in Fig. 1 contact unit and optical fiber coordinate schematic diagram;

Fig. 5 be in the present invention plug casing and X, Y-direction float installing mechanism coordinate schematic diagram;

Fig. 6 is the vertical view of Fig. 2;

Fig. 7 is that the C-C of Fig. 6 is to cut-open view;

Fig. 8 is the B place enlarged drawing of Fig. 6;

Fig. 9 is the D place enlarged drawing in Fig. 7;

Figure 10 is the structural representation of optical fiber backboard in the present invention;

Figure 11 is the manufacturing process schematic diagram of optical fiber backboard in Figure 10;

Figure 12 is the structural representation of the first optical fiber backboard unit in Figure 10;

Figure 13 is the structural representation of the second optical fiber backboard unit in Figure 10;

Figure 14 is the structural representation of substrate tape in Figure 10;

Figure 15 is the Fiber connection schematic diagram in the present invention between daughter board plug and another one plug.

Embodiment

The embodiment of cable assembly is as shown in Fig. 1 ~ 15: cable assembly comprises the joints of optical fibre and optical fiber backboard, the daughter board plug on the daughter board in corresponding rack is installed on when the joints of optical fibre are a use in the present embodiment, daughter board plug 3 comprises plug casing, plug casing comprises male component housing 8, locking shell 6 and flotation shell 5, wherein the front end of male component housing is inserted terminal, male component housing is made up of insulating material, contact unit is provided with in male component housing, the pin body 11 arranged before and after contact unit comprises and limit base 12, in the present embodiment, limit base is binary limit base, pin body comprises MT contact pin, limit base 12 is provided with elastic arm 8, elastic arm 8 is provided with lock projection 9, male component housing 8 is provided with the draw-in groove coordinated with lock projection 9, the first spring 10 is top-loaded with between limit base 12 and pin body 11, limit base there is the main channel passed through along the longitudinal direction for corresponding optical fiber and for optical fiber 14 along the accessory channel 13 passed through perpendicular to fore-and-aft direction, in the present embodiment, optical fiber is fibre ribbons structure, limit base is square sleeve structure, accessory channel 13 is arranged at edges and corners of direction sleeve.By the setting of accessory channel, limit base 12 can take out along perpendicular on fore-and-aft direction by optical fiber, like this after damage appears in limit base, only needs to change limit base.

The flat block structure that male component housing 8 extends along the vertical direction for thickness, width extends in left-right direction, male component housing is provided with resilient push 21, resilient push 21 has end and male component housing 8 is fixedly installed, the head end putter body 22 that overhangs of elasticity forward, resilient push is arranged at male component housing upper end, has the deformation gap 20 for resilient push elastic deformation along the vertical direction between male component housing and the projecting end of putter body.The projecting end of putter body 22 is provided with the housing Stop structure 24 coordinated with flotation shell 5 block to limit flotation shell movement forward, flotation shell is provided with the locking pushing part 23 of pushing tow housing Stop structure 24, the present embodiment middle shell Stop structure 24 is for being convexly equipped in the projection of putter body 22 upper end, putter body 22 is provided with in the front side of housing Stop structure for before male component housing is by respective socket part case block by the load portion 25 of Socket casing pushing tow, load portion 25 is for being made described housing Stop structure get out of the way flotation shell 5 by Socket casing pushing tow after making the projecting end elastic deformation of putter body, flotation shell 5 can move by opposing plug part case 8 in the longitudinal direction, load portion 25 is in the upside of putter body.The Z-direction that can be realized the corresponding male component housing of flotation shell by said structure is floated, and what Z-direction was corresponding is fore-and-aft direction.

Male component housing is provided with for linking up with the locking on backboard socket the locking slot 28 coordinated, locking hook 27 is with the relocatable elastic hook of slotting elasticity tongue 26, locking shell 6 along the longitudinal direction guiding movement is assemblied on male component housing 8, be provided with for applying forward to the second spring 10 of acting force to locking shell between locking shell 6 and male component housing 8, locking shell 6 have for perpendicular on fore-and-aft direction spacing with locking hook 27 coordinate to prevent from lock the horizontal pressure portion 29 linking up with in by locking slot and in the longitudinal direction with lock the longitudinal pressure-bearing portion 30 linking up with pushing tow and coordinate, longitudinal pressure-bearing portion 30 is positioned at the front side of horizontal pressure portion 29, at daughter board plug and backboard socket to time slotting, the longitudinal pressure-bearing portion 30 of end pushing tow of locking hook 27, move after making locking shell 6, after locking hook 27 enters into locking slot 28, no longer pushing tow locking shell is linked up with in locking, by the acting force of the second spring, locking shell moves forward, horizontal pressure portion 29 in locking shell moves to locking hook position, spacing to locking hook by horizontal pressure portion 29, prevent locking hook from deviating from by locking slot 28, to realize the locking of daughter board plug and backboard socket.Locking shell is provided with the gathering sill 35 extended along the longitudinal direction, the rear side cell wall 37 of gathering sill 35 is from the bottom to top gradually towards the skew wall of top rake, flotation shell is provided with the barb 36 being arranged in gathering sill, barb 36 can move in gathering sill 35, barb 36 is adaptive with the rear side cell wall gradient of gathering sill 35, and such group strip flotation shell when moving backwards, and barb 36 can move backwards with locking shell 6, horizontal pressure portion is removed by locking hook, thus realizes unlocking.Realized the unblock of locking shell by rock plate, be highly suitable for daughter board density large, do not have space directly to go to draw in the environment of locking shell and use at all.

X is passed through in the left and right sides of flotation shell, the Y-direction installing mechanism that floats is installed on daughter board, X is left and right directions to correspondence, what Y-direction was corresponding is above-below direction, X, the Y-direction installing mechanism that floats comprises front limit block 16, rear limited block 18 and before being connected to, joint pin 15 between rear limited block, front limit block 16 is fixed on daughter board by screw 17, the left and right sides of flotation shell is provided with the floating hole 50 that axis extends along the longitudinal direction, the hole wall in floating hole offers for joint pin along X to the side wall channels loaded, float the flying height had between hole and joint pin on left and right directions and above-below direction.When can prevent daughter board from docking with backboard like this, may occur that headstock is to not inserting, and break the problem of parts.Fig. 7 middle term 2-1 represents Socket casing.

Optical fiber backboard comprises the first optical fiber backboard unit 45 and the second optical fiber backboard unit 46, first optical fiber backboard unit and comprises in the first backplane substrate 43, first backplane substrate and be provided with four for carrying the first fibre ribbon 44 of light signal along the longitudinal direction; Second optical fiber backboard unit 46 comprises the second fibre ribbon 42, second backplane substrate is provided with four for carrying the second fibre ribbon 41 of light signal along the longitudinal direction, first fibre ribbon, the second fibre ribbon are all connected on daughter board plug, and first, second backplane substrate is made by flexible material.First backplane substrate 43 is provided with the first fibre ribbon 47 running through the first backplane substrate along the first backplane substrate thickness of slab direction, the left end of the first fibre ribbon 47 extends on the left surface of the first backplane substrate, optical fiber in each first fibre ribbon wears the right side intersection restructuring of groove at the first backboard, one is synthesized in the left side wherein having two the first fibre ribbons to wear groove at the first backboard, intersect restructuring again on the right side that groove worn by the first backboard, the centre that the first fibre ribbon 47 is in the first backplane substrate 43 keeps left position.Second fibre ribbon 42 is provided with the second backboard running through the second fibre ribbon 42 along the second backplane substrate thickness of slab direction and wears groove 48, second backboard is worn centre that groove 48 is in the second backplane substrate and to be kept left position, the right-hand member that groove 48 worn by second backboard extends on the right flank of the second backplane substrate, and the optical fiber in each second fibre ribbon 41 wears the right side intersection restructuring of groove at the second backboard.Second backplane substrate comprises section 42-2 on the left of section 42-1 on the right side of the second backboard, the second backboard and is connected to the second backboard interlude on the left of the second backboard on the right side of section and the second backboard between section, the lead-in wire terminal 41-1 of the second fibre ribbon is arranged on the left of the second backboard on section 42-2, and the leading-out terminal 41-2 of the second fibre ribbon to be arranged on the right side of the second backboard on section 42-1, first backplane substrate comprises section 43-1 on the right side of the first backboard, section 43-2 and the first backboard interlude of being connected on the left of the first backboard on the right side of section and the first backboard between section on the left of first backboard, the lead-in wire terminal 44-1 of the first fibre ribbon to be arranged on the left of the first backboard on section 43-2, the leading-out terminal 44-2 of the first fibre ribbon to be arranged on the right side of the first backboard on section 43-1, wherein the second backboard interlude is arranged in the first backboard and wears in groove, first backboard interlude is arranged in the second backboard and wears in groove, on the right side of second backboard, section is in the top of section on the right side of the first backboard, on the left of second backboard, section is in the below of section on the left of the first backboard, thus make the lead-in wire terminal of the second fibre ribbon be positioned at below the lead-in wire terminal of the first fibre ribbon, the leading-out terminal of the second optical fiber is positioned at above the leading-out terminal of the first fibre ribbon, the optical fiber so just achieved between backboard fiber unit is arranged in a crossed manner in the vertical direction.

The manufacturing process of the optical fiber backboard unit in above-mentioned optical fiber backboard is: first provide the matrix with pressure-sensitive, pressure-sensitive can be the attribute that matrix inherently has, such as matrix is the transparent adhesive film structure formed after glue curing, film structure has pressure-sensitive; Pressure-sensitive also can be on matrix, apply pressure-sensitive adhesive layer and make matrix have pressure-sensitive, such as matrix is the substrate tape with pressure-sensitive adhesive layer.Now for substrate tape 49 as matrix, the making of optical fiber backboard unit is described, fibre ribbon is arranged in the surface of substrate tape, the optical fiber of fibre ribbon carries out intersection restructuring on substrate tape surface, the optical fiber combination of intersecting after recombinating forms complete fibre ribbon or part fiber band, subsequently at substrate tape and optical fiber surface coating encapsulated layer, protection is formed to optical fiber, that is the backplane substrate in the present invention is made up of substrate tape and encapsulated layer, finally cutting out backboard in the side of backplane substrate wears groove, the second optical fiber backboard unit can be made with identical layout.The manufacturing process of optical fiber backboard is: the fluting position of first, second optical fiber backboard unit is plugged each other combination as shown in figure 11: after two optical fiber backboard unit close insert group, by the second optical fiber backboard matrix along A direction turnover in Figure 11, until each leading-out terminal on the second optical fiber backboard unit to be on the first optical fiber backboard unit directly over each lead-in wire terminal respectively, each lead-in wire terminal on second optical fiber backboard unit to be on the first optical fiber backboard unit immediately below each lead-in wire terminal respectively, realizes between row and row interlaced of fibre ribbon.

During use, this daughter board plug 3 is installed on daughter board 4, the backboard socket 2 coordinated with it is installed on backboard 1, the hand-holdable daughter board of operating personnel makes daughter board plug and backboard socket to inserting, X, the Y-direction installing mechanism that floats can prevent daughter board plug, backboard socket occurs the problem of not inserting, daughter board plug and backboard socket are to after inserting, the locking slot first hooked on male component housing is linked up with in locking on backboard socket, horizontal pressure portion in locking shell pushes down locking hook, daughter board plug and backboard socket have been locked, along with the continuation of daughter board moves forward, flotation shell promotes resilient push, resilient push continues to move forward with male component housing, gradually, load portion pushing tow in Socket casing and resilient push makes the projecting end elastic deformation down of putter body, under the effect of Socket casing, housing Stop structure in putter body can be thrown off completely with flotation shell, daughter board continues reach, flotation shell is only had to move forward, daughter board is in place, flotation shell is also by Socket casing block, flotation shell is in location free procedure, male component housing can move backward until lock hook and again play and act under the effect of the first spring.When needs daughter board plug is separated with backboard socket, pull daughter board, flotation shell moves backwards, and after the rear wall in the barbs hold locking shell on flotation shell, flotation shell moves after can driving locking shell and realizes unlocking.In other embodiment of the joints of optical fibre: the joints of optical fibre can also be adaptive backboard socket with daughter board plug, and certain joints of optical fibre also can be used in other environment beyond rack; Daughter board plug can also be LC plug; Z-direction in certain above-described embodiment is floated, and X, the Y-direction installing mechanism that floats also can be applied in electric connector, and now daughter board plug can be a plug; The deformation direction of the projecting end of putter body also can be left and right directions, and now putter body can be arranged at the side of male component housing; Housing Stop structure may not be a projection cube structure, such as staircase structure low after height before the upper surface of putter body is one, now housing Stop structure can be made up of the step surface of staircase structure; Limit base also can adopt monomer structure.The second backplane substrate be made up of flexible material facilitates the making of light signal transmission device, and first, second backplane substrate can bend simultaneously, makes this signal transmitting apparatus go for various operating angle; First backboard is worn slot and to be kept left in the centre of the first backplane substrate position, and the intersection restructuring of optical fiber simultaneously occurs in the right side that groove worn by the first backboard, and contribute to the size reducing backplane substrate like this, the miniaturization being beneficial to light signal transmission device makes; Second backplane substrate is arranged the second backboard and wear groove, the projection that first, second backplane substrate just can be implemented on above-below direction like this overlaps, to arrange more fibre ribbon in limited space.In other embodiment of this light signal transmission device: the second backboard in the second backplane substrate is worn groove and can not also be established, now two first, second fibre ribbons on right side can not be established; Certain first backboard is worn groove and also can not be extended on the left surface of the first backplane substrate; The number of the fibre ribbon on each optical fiber backboard unit can also be arranged as required, such as two, three or other number; First backplane substrate also can be made up of rigid material; Second backplane substrate also can be made up of rigid material; When the size of backplane substrate is larger, backboard is worn groove and can also be arranged at the centre position of backplane substrate or centre and keep right position.

Claims (5)

1. cable assembly, comprise the joints of optical fibre and optical fiber backboard, optical fiber backboard comprises the first optical fiber backboard unit and the second optical fiber backboard unit, first optical fiber backboard unit comprises the first backplane substrate, first backplane substrate is provided with the first fibre ribbon be connected with the described joints of optical fibre for carrying light signal along the longitudinal direction, second optical fiber backboard unit comprises the second backplane substrate, second backplane substrate is provided with the second fibre ribbon be connected with the described joints of optical fibre, it is characterized in that: the first backplane substrate is provided with the first backboard running through described first backplane substrate along the first backplane substrate thickness of slab direction and wears groove, section on the right side of the second backboard that the leading-out terminal that second backplane substrate comprises confession second optical fiber be in above described first backplane substrate is arranged, section and the second backboard interlude of being connected on the left of described second backboard on the right side of section and the second backboard between section on the left of the second backboard that the lead-in wire terminal being in confession second optical fiber below described first backplane substrate is arranged, second backboard interlude is arranged in described first backboard and wears in groove, the lead-in wire terminal of the second fibre ribbon is positioned at below the lead-in wire terminal of the first fibre ribbon, the leading-out terminal of the second optical fiber is positioned at above the leading-out terminal of the first fibre ribbon.

2. cable assembly according to claim 1, is characterized in that: described second backplane substrate is made up of flexible material.

3. cable assembly according to claim 1, it is characterized in that: the first optical fiber is with at least two, optical fiber in each first fibre ribbon intersects restructuring on the right side that groove worn by described first backboard, the first backboard is worn centre that groove is in the first backplane substrate and to be kept left position.

4. the cable assembly according to claim 1 ~ 3 any one, it is characterized in that: the left end that groove worn by the first backboard extends on the left surface of described first backplane substrate, second backplane substrate is provided with the second backboard that the right-hand member that runs through described second backplane substrate along the second backplane substrate thickness of slab direction extends on the right flank of described second backplane substrate and wears groove, section on the right side of the first backboard that the leading-out terminal that first backplane substrate comprises confession second fibre ribbon be positioned on the right side of described second backboard below section is arranged, section and the first backboard interlude of being connected on the left of described first backboard on the right side of section and the first backboard between section on the left of the first backboard that the lead-in wire terminal of confession second fibre ribbon on the left of described second backboard above section is arranged, first backboard interlude is arranged in described second backboard and wears in groove.

5. cable assembly according to claim 4, is characterized in that: described first backplane substrate is made up of flexible material.