CN109068472B

CN109068472B - Double-sided flexible soft board and assembly fixture thereof

Info

Publication number: CN109068472B
Application number: CN201810973831.5A
Authority: CN
Inventors: 杨国民; 袁航空; 王亚丽
Original assignee: Wuhan Hengtaitong Technology Co ltd
Current assignee: Wuhan Hengtaitong Technology Co ltd
Priority date: 2018-08-24
Filing date: 2018-08-24
Publication date: 2020-10-30
Anticipated expiration: 2038-08-24
Also published as: CN109068472A

Abstract

The invention relates to a double-sided flexible soft board and an assembly fixture thereof, comprising a flexible soft board body, wherein the flexible soft board body adopts a double-sided board structure; the front surface of the flexible soft board body is provided with a main via hole area and a standard pad area, a group of main via holes with one-to-one correspondence of an electrical network and the electrical network of the optical device pins to be manufactured or tested are arranged in the main via hole area, and a group of standard pads with one-to-one correspondence to the electrical network of the main via holes are arranged in the standard pad area; the back of the flexible soft board body is provided with a test pad area, and a group of test pads which correspond to the standard pad electrical network one to one are arranged in the test pad area. The invention has the beneficial effects that: the flexible soft board body testing device has the advantages that the double-panel structure is adopted, the space is fully utilized, the testing pad area is arranged on the back, the reliability and the yield of the flexible soft board body testing are not required to be met under the condition that the non-standard pad area is expanded, and the industrial testing standard can be met.

Description

Double-sided flexible soft board and assembly fixture thereof

Technical Field

The invention relates to the technical field of optical communication, in particular to a double-sided flexible soft board and an assembly fixture thereof.

Background

At present, in the manufacturing process of a rigid Printed Circuit Board (PCB), a flexible Printed Circuit board (FPC) or a rigid-flex Circuit board (FPC), a Circuit layout design and a layout design of components (such as resistors, capacitors, integrated circuits, etc.) are required, and then a Circuit wiring is performed according to a preset path and a pad is formed at a preset position. With space and volume limitations and with the trend towards high integration of optoelectronic devices and communication modules, the dimensions imposed by industry standards are becoming smaller and smaller. The size of the flexible plate is smaller and smaller, and the bonding pads are more and more dense; therefore, in the manufacturing and testing processes of the optoelectronic device and the module, because the bonding pads of the flexible board are too dense, the bonding pad connection of the flexible board and the testing circuit board is in poor butt joint or even in misplaced press fit. Once powered, there is a significant chance of damage to the optoelectronic devices and modules being manufactured or tested. And as the flexibility of the multilayer board is far lower than that of the single-layer board, the flexible board is damaged by repeated positioning and assembly in multi-process manufacturing and testing of photoelectric devices and modules, so that the appearance and the performance are influenced, a product using the flexible board needs to be replaced by a new flexible board at high temperature before being sold, and the product is easily damaged again in the high-temperature replacement process to cause failure. Due to the defects of the flexible board with high-density pads and the press-fit method thereof, the photoelectric device and the communication module are damaged or failed in the manufacturing and testing processes, and the reject ratio is increased.

Disclosure of Invention

The invention aims to solve the technical problem of the prior art and provides a double-sided flexible soft board and an assembly fixture thereof.

The technical scheme for solving the technical problems is as follows:

according to one aspect of the invention, a double-sided flexible soft board is provided, which comprises a flexible soft board body, wherein the flexible soft board body adopts a double-sided board structure; the front surface of the flexible soft board body is provided with a main via hole area and a standard pad area, a group of main via holes with one-to-one correspondence of an electrical network and an electrical network of an optical device pin to be manufactured or tested are arranged in the main via hole area, and a group of standard pads with one-to-one correspondence to the electrical network of the main via holes are arranged in the standard pad area; and a testing pad area is arranged on the back surface of the flexible soft board body, and a group of testing pads which correspond to the standard pad electrical network one to one are arranged in the testing pad area.

The invention has the beneficial effects that: the flexible soft board body adopts a double-sided board structure, the space is fully utilized, the testing pad area is arranged on the back, the reliability and yield of the flexible soft board body test can be met without expanding the non-standard pad area while the standard pad distribution and the electrical performance are not influenced, and the industrial test standard can also be met; when the flexible soft board is tested, the condition that the connection and the butt joint of the flexible soft board body and the welding disc of the circuit board are poor or even the flexible soft board is in a staggered press fit is not easy to occur, the damage to the flexible soft board in the testing process is reduced, and the replacement of the flexible soft board after the testing is finished is reduced, so that the reliability and the yield of an optical device or an optical module in the testing process are improved.

On the basis of the technical scheme, the invention can be further improved as follows.

Further: the test pads are distributed in a multi-ring shape, and the test pads on two adjacent rings are distributed in a staggered mode.

The beneficial effects of the further scheme are as follows: the number of the circular rings and the radius of the circular rings distributed in the multi-circular ring shape can be changed according to the change of the number of the test bonding pads in actual conditions, so that the distance between the test bonding pads is ensured to meet the requirements of industrial test standards.

Further: the size of each testing pad is larger than that of each standard pad, and the interval between every two adjacent testing pads is larger than that between every two adjacent standard pads.

The beneficial effects of the further scheme are as follows: the probability of the dislocation connection is reduced.

Further: a through hole area is further arranged on the flexible soft board body and is positioned between the test pad area and the standard pad area; and a plurality of penetrating positioning holes are arranged in the penetrating hole area, are positioned on the same straight line and are unevenly distributed.

The beneficial effects of the further scheme are as follows: through setting up the locating hole that runs through, be convenient for realize the installation location of flexible soft board body on the circuit board.

According to another aspect of the invention, an assembly fixture for a double-sided flexible soft board is provided, which is used for assembling the double-sided flexible soft board and comprises a bottom board, a circuit board, a guide mechanism and a push rod device, wherein the circuit board and the guide mechanism are both fixedly arranged at the top of the bottom board, and the push rod device is fixedly arranged at the top of the guide mechanism; the guide mechanism is of a door-shaped structure with central symmetry, and the circuit board is provided with a pair of mounting through holes for fixedly mounting the guide mechanism on the bottom plate; a pressing plate and a plurality of pressing blocks are arranged in the guide mechanism, the pressing plate is in sliding fit with the guide mechanism, and the pressing blocks are symmetrically arranged at the bottom of the pressing plate; the flexible soft board body is fixedly arranged on the circuit board below the pressing block; and a push rod of the push rod device penetrates through the top of the guide mechanism and is fixedly connected with the top of the pressing plate.

The invention has the beneficial effects that: the flexible soft board body is correspondingly arranged below the pressing block, is positioned and fixed, and the pressing plate is pushed by the push rod device, so that the pressing block moves downwards and presses the test bonding pad of the flexible board body, and subsequent assembly is facilitated; the guide mechanism is of a door-shaped structure with central symmetry, so that the pressure exerted on the pressing plate by the push rod device is balanced, and the assembly precision of the flexible soft plate body is improved.

Further: the guide mechanism comprises a left vertical plate, a right vertical plate, an upper transverse plate, a pair of guide shafts, an upper guide shaft fixing plate and a pair of lower lug type guide shaft fixing blocks, the left vertical plate and the right vertical plate are symmetrically installed on the bottom plate through the installation through holes, the upper transverse plate fixing plate is arranged at the tops of the left vertical plate and the right vertical plate in an overhead mode, two ends of the upper guide shaft fixing plate are fixedly connected with the inner walls of the left vertical plate and the right vertical plate respectively, the pair of lower lug type guide shaft fixing blocks are fixedly connected with the inner walls of the left vertical plate and the right vertical plate respectively, the upper guide shaft fixing plate is located above the lower lug type guide shaft fixing blocks, and the upper ends and the lower ends of the pair of guide shafts are fixedly connected with the upper guide shaft fixing plate and the lower lug type guide shaft fixing blocks respectively; and two ends of the pressure plate are respectively in sliding fit with the pair of guide shafts.

The beneficial effects of the further scheme are as follows: the pair of guide shafts is fixed through the guide shaft upper fixing plate and the pair of ear-shaped guide shaft lower fixing blocks, so that the guide sliding of the pressing plate is realized.

Further: and a plurality of positioning pins which are in one-to-one correspondence with the through positioning holes are arranged on the circuit board.

The beneficial effects of the further scheme are as follows: the positioning pin is used for installing and positioning the flexible soft board body.

Further: an odd number of reset springs are fixedly arranged between the guide shaft upper fixing plate and the pressing plate, the reset springs are symmetrically arranged, and the reset spring positioned in the middle is sleeved on a push rod of the push rod device.

Further: an even number of reset springs are fixedly arranged between the fixed plate and the pressure plate on the guide shaft, and the reset springs are symmetrically arranged on two sides of the push rod device.

The beneficial effect of the two-step scheme is as follows: through setting up reset spring, push down the effect that the clamp plate played the buffering to the push rod device, reduce the briquetting to the impact of flexible soft board body, reset spring can also play the effect of clamp plate that resets in addition, and is simple high-efficient.

Further: the pressing block is made of soft materials.

The beneficial effects of the further scheme are as follows: the rigid impact of the pressing block on the flexible soft board body can be relieved, and the test welding pad is protected.

Drawings

FIG. 1 is a schematic front view of a flexible printed circuit board according to the present invention;

FIG. 2 is a schematic view of the back structure of the flexible soft board of the present invention;

FIG. 3 is a schematic perspective view of the assembly fixture of the present invention;

in the drawings, the names of the components represented by the respective reference numerals are as follows:

100. the flexible soft board comprises a flexible soft board body, 110, a main via hole area, 111, a main via hole, 120, a test pad area, 121, a test pad, 130, a through hole area, 131, a through positioning hole, 140, a standard pad area, 141, a standard pad, 200, a bottom board, 300, a circuit board, 310, a positioning pin, 400, a guide mechanism, 410, a left vertical board, 420, a right vertical board, 430, an upper transverse board, 440, a guide shaft upper fixing board, 450, a guide shaft, 460, an ear-shaped guide shaft lower fixing block, 470, a reset spring, 500, a push rod device, 600, a pressing plate, 610 and a pressing block.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the invention.

As shown in fig. 1 and fig. 2, a double-sided flexible soft board comprises a flexible soft board body 100, wherein the flexible soft board body 100 adopts a double-sided board structure; a main via hole area 110 and a standard pad area 140 are arranged on the front surface of the flexible soft board body 100, a group of main via holes 111, of which the electrical networks correspond to the electrical networks of the optical device pins to be manufactured or tested one by one, are arranged in the main via hole area 110, and a group of standard pads 141, of which the electrical networks correspond to the electrical networks of the main via holes 111 one by one, are arranged in the standard pad area 140; the standard pad 141 complies with industry standard regulations; a test pad area 120 is arranged on the back surface of the flexible soft board body 100, and a group of test pads 121 corresponding to the standard pads 141 in an electrical network one to one are arranged in the test pad area 120.

The test pads 121 are distributed in a plurality of circular rings, and the test pads 121 on two adjacent circular rings are distributed in a staggered manner; the number of the circular rings and the radius of the circular rings distributed in the multiple circular rings can be changed according to the change of the number of the test pads 121 in actual situations, so as to ensure that the distance between the test pads 121 meets the requirements of the industry test standard.

The size of each of the test pads 121 is larger than that of each of the standard pads 141, and the interval between two adjacent test pads 121 is larger than that between two adjacent standard pads 141.

The flexible soft board body 100 adopts a double-sided board structure, and after the double-sided board is formed by using a double-sided PI board and copper-clad board materials, a layer of protective film is respectively added on the front side and the back side of the double-sided board to form a circuit board with double-layer conductors. The double-sided flexible soft board is characterized in that a layer of conductive pattern formed by etching is respectively arranged on the front side and the back side of the base film, the patterns on the two sides of the insulating material are connected through the metallized holes to form a conductive path so as to meet the flexibility design and use functions, and the covering film can protect single-sided and double-sided wires and indicate the position of element placement.

A through hole region 130 is further disposed on the flexible printed circuit board body 100, and the through hole region 130 is located between the test pad region 120 and the standard pad region 140; a plurality of through positioning holes 131 are formed in the through hole region 130, and the through positioning holes 131 are not uniformly distributed and are positioned on the same straight line.

As shown in fig. 3, an assembling jig for a double-sided flexible printed circuit board is used for assembling the double-sided flexible printed circuit board, and includes a base plate 200, a circuit board 300, a guide mechanism 400 and a push rod device 500, wherein the circuit board 300 and the guide mechanism 400 are both fixedly disposed on the top of the base plate 200, and the push rod device 500 is fixedly disposed on the top of the guide mechanism 400; the guide mechanism 400 is a door-shaped structure with central symmetry, and the circuit board 300 is provided with a pair of mounting through holes for fixedly mounting the guide mechanism 400 on the bottom plate 200; a pressing plate 600 and a plurality of pressing blocks 610 are arranged in the guide mechanism 400, the pressing plate 600 is in sliding fit with the guide mechanism 400, and the plurality of pressing blocks 610 are symmetrically arranged at the bottom of the pressing plate 600; the flexible soft board body 100 is fixedly arranged on the circuit board 300 below the pressing block 610; the push rod of the push rod device 500 passes through the top of the guide mechanism 400 and is fixedly connected with the top of the press plate 600.

The guide mechanism 400 comprises a left vertical plate 410, a right vertical plate 420, an upper transverse plate 430, a pair of guide shafts 450, a guide shaft upper fixing plate 440 and a pair of ear-shaped guide shaft lower fixing blocks 460, the left and

right risers

410 and 420 are symmetrically installed on the base plate 200 through the installation through-holes, the upper horizontal plate 430 is fixedly arranged on the top of the left vertical plate 410 and the right vertical plate 420, two ends of the guide shaft upper fixing plate 440 are respectively fixedly connected with the inner walls of the left vertical plate 410 and the right vertical plate 420, a pair of ear-shaped guide shaft lower fixing blocks 460 are respectively fixedly connected with the inner walls of the left vertical plate 410 and the right vertical plate 420, the guide shaft upper fixing plate 440 is positioned above the ear-shaped guide shaft lower fixing block 460, and the upper and lower ends of the pair of guide shafts 450 are respectively fixedly connected with the guide shaft upper fixing plate 440 and the ear-shaped guide shaft lower fixing block 460; both ends of the pressing plate 600 are respectively in sliding fit with the pair of guide shafts 450.

The circuit board 300 is provided with a plurality of positioning pins 310 corresponding to the through positioning holes 131 one to one for installing and positioning the flexible printed circuit board body 100.

An odd number of return springs 470 are fixedly arranged between the guide shaft upper fixing plate 440 and the pressing plate 600, the return springs 470 are symmetrically arranged, and the return springs 470 positioned in the middle are sleeved on the push rod of the push rod device 500.

An even number of return springs 470 are fixedly arranged between the guide shaft upper fixing plate 440 and the pressing plate 600, and the return springs 470 are symmetrically arranged on two sides of a push rod of the push rod device 500.

In this embodiment, the number of the pressing blocks 610 is two, and the two pressing blocks 610 are symmetrically arranged at the bottom of the pressing plate 600 by taking the push rod of the push rod device 500 as a center; the press block 610 is made of a flexible material, such as super glue.

The push rod device 500 is an electric push rod or an air cylinder, and in this embodiment, the push rod device 500 is preferably an electric push rod.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A double-sided flexible soft board is characterized in that: the flexible soft board comprises a flexible soft board body (100), wherein the flexible soft board body (100) adopts a double-sided board structure; a main via hole area (110) and a standard pad area (140) are arranged on the front surface of the flexible soft board body (100), a group of main via holes (111) with an electrical network corresponding to an electrical network of optical device pins to be manufactured or tested are arranged in the main via hole area (110), and a group of standard pads (141) with an electrical network corresponding to the main via holes (111) are arranged in the standard pad area (140); a testing pad area (120) is arranged on the back surface of the flexible soft board body (100), and a group of testing pads (121) which correspond to the standard pads (141) in an electrical network one by one are arranged in the testing pad area (120); the test bonding pads (121) are distributed in a multi-ring shape, and the test bonding pads (121) on two adjacent rings are distributed in a staggered manner;

the size of each test pad (121) is larger than that of each standard pad (141), and the interval between two adjacent test pads (121) is larger than that between two adjacent standard pads (141); a through hole area (130) is further arranged on the flexible soft board body (100), and the through hole area (130) is located between the test pad area (120) and the standard pad area (140); a plurality of through positioning holes (131) are arranged in the through hole area (130), and the through positioning holes (131) are located on the same straight line and are not uniformly distributed.

2. The utility model provides an assembly jig of two-sided flexible soft board which characterized in that: the assembly for the double-sided flexible printed circuit board of claim 1, comprising a base plate (200), a circuit board (300), a guide mechanism (400) and a push rod device (500), wherein the circuit board (300) and the guide mechanism (400) are fixedly arranged on the top of the base plate (200), and the push rod device (500) is fixedly arranged on the top of the guide mechanism (400); the guide mechanism (400) is of a door-shaped structure with central symmetry, and a pair of mounting through holes for fixedly mounting the guide mechanism (400) on the bottom plate (200) are formed in the circuit board (300); a pressing plate (600) and a plurality of pressing blocks (610) are arranged in the guide mechanism (400), the pressing plate (600) is in sliding fit with the guide mechanism (400), and the pressing blocks (610) are symmetrically arranged at the bottom of the pressing plate (600); the flexible soft board body (100) is fixedly arranged on the circuit board (300) below the pressing block (610); the push rod of the push rod device (500) penetrates through the top of the guide mechanism (400) and is fixedly connected with the top of the pressing plate (600).

3. The assembly jig for the double-sided flexible printed circuit board according to claim 2, wherein: the guide mechanism (400) comprises a left vertical plate (410), a right vertical plate (420), an upper transverse plate (430), a pair of guide shafts (450), a guide shaft upper fixing plate (440) and a pair of ear-shaped guide shaft lower fixing blocks (460), wherein the left vertical plate (410) and the right vertical plate (420) are symmetrically installed on the bottom plate (200) through the installation through holes, the upper transverse plate (430) is fixedly arranged at the tops of the left vertical plate (410) and the right vertical plate (420), two ends of the guide shaft upper fixing plate (440) are respectively fixedly connected with the inner walls of the left vertical plate (410) and the right vertical plate (420), the pair of ear-shaped guide shaft lower fixing blocks (460) are respectively fixedly connected with the inner walls of the left vertical plate (410) and the right vertical plate (420), and the guide shaft upper fixing plate (440) is positioned above the ear-shaped guide shaft lower fixing blocks (460), the upper end and the lower end of the guide shaft (450) are respectively and fixedly connected with the guide shaft upper fixing plate (440) and the ear-shaped guide shaft lower fixing block (460); two ends of the pressure plate (600) are respectively in sliding fit with the pair of guide shafts (450).

4. The assembly jig for the double-sided flexible printed circuit board according to claim 2, wherein: the circuit board (300) is provided with a plurality of positioning pins (310) which are in one-to-one correspondence with the through positioning holes (131).

5. The assembly jig for the double-sided flexible printed circuit board as claimed in claim 3, wherein: an odd number of reset springs (470) are fixedly arranged between the guide shaft upper fixing plate (440) and the pressing plate (600), the reset springs (470) are symmetrically arranged, and the reset spring (470) positioned in the middle is sleeved on a push rod of the push rod device (500).

6. The assembly jig for the double-sided flexible printed circuit board as claimed in claim 3, wherein: an even number of reset springs (470) are fixedly arranged between the guide shaft upper fixing plate (440) and the pressure plate (600), and the reset springs (470) are symmetrically arranged on two sides of a push rod of the push rod device (500).

7. The assembly jig for the double-sided flexible printed circuit board according to claim 2, wherein: the pressing block (610) is made of soft materials.