CN116939979A - Printed circuit board bearing jig - Google Patents

Abstract

The invention relates to the technical field of printed circuit board processing and production, and discloses a printed circuit board bearing jig. The printed circuit board bearing jig comprises a main bearing piece, an auxiliary bearing component and a driving component, wherein the main bearing piece is used for bearing a printed circuit board and is provided with a first positioning through hole; the auxiliary bearing assembly is arranged below the main bearing piece, a positioning column and a first magnetic piece are arranged on the auxiliary bearing assembly, and the positioning column can be arranged in the first positioning through hole and extend out of the upper surface of the first positioning through hole; the driving assembly is arranged below the auxiliary bearing assembly in a position adjustable manner along the vertical direction, a second magnetic piece is arranged on the driving assembly, and when the driving assembly is close to the auxiliary bearing assembly, the second magnetic piece and the first magnetic piece are magnetically attracted, so that the positioning column does not extend out of the upper surface of the first positioning through hole. The invention can realize the bearing of the printed circuit board during printing, can realize the bearing of the printed circuit board during bonding, has lower cost and is more accurate and reliable.

Description

Printed circuit board bearing jig

Technical Field

The invention relates to the technical field of printed circuit board processing and production, in particular to a printed circuit board bearing jig.

Background

In the process of printed circuit board processing production, the printed circuit boards need to be printed and bonded in sequence. In the prior art, two independent jigs are generally used for printing and bonding a printed circuit board, resulting in an increase in production cost. Meanwhile, when the printed circuit board is transferred into the bonding jig after printing, a mechanical arm or manpower is usually required to be added, so that the cost is further increased; and there is a risk of damaging the printed circuit board during the transfer process.

Therefore, a carrier tool for a printed circuit board is needed to solve the above-mentioned problems.

Disclosure of Invention

Based on the above, the invention aims to provide a bearing jig for a printed circuit board, which not only can realize bearing when the printed circuit board is printed, but also can realize bearing when the printed circuit board is bound, and has lower cost and more accurate and reliable bearing.

In order to achieve the above purpose, the invention adopts the following technical scheme:

the printed circuit board bears tool includes:

the main bearing piece is used for bearing the printed circuit board and is provided with a first positioning through hole;

the auxiliary bearing assembly is arranged below the main bearing piece, a positioning column and a first magnetic piece are arranged on the auxiliary bearing assembly, and the positioning column can be arranged on the first positioning through hole and extend out of the upper surface of the first positioning through hole;

the driving assembly is arranged below the auxiliary bearing assembly in a position adjustable manner along the vertical direction, a second magnetic piece is arranged on the driving assembly, and when the driving assembly is close to the auxiliary bearing assembly, the second magnetic piece and the first magnetic piece are magnetically attracted, so that the positioning column does not extend out of the upper surface of the first positioning through hole.

As a preferred solution of the printed circuit board carrying jig, the printed circuit board carrying jig is provided with a reset assembly configured to be able to drive the auxiliary carrying assembly close to the main carrying member.

As a preferred scheme of the printed circuit board bearing jig, the resetting component comprises a guide pillar and a resetting piece sleeved on the guide pillar, one end of the guide pillar penetrates through the auxiliary bearing component and is connected with the main bearing piece, a boss is arranged at the other end of the guide pillar, and the resetting piece is abutted between the auxiliary bearing component and the boss.

As a preferred scheme of the printed circuit board bearing jig, the auxiliary bearing assembly comprises a first bottom plate and a second bottom plate arranged below the first bottom plate, the first bottom plate is provided with a mounting edge extending out of the second bottom plate, the mounting edge is provided with a guide hole, and the guide post penetrates through the guide hole.

As a preferred scheme of the printed circuit board bearing jig, the two sides of the first bottom plate are respectively provided with the mounting edges, the first magnetic pieces are arranged on the mounting edges, and each mounting edge is respectively provided with a plurality of guide holes and a plurality of first magnetic pieces.

As a preferable scheme of the printed circuit board bearing jig, the positioning column is arranged on the second bottom plate, and the first bottom plate is provided with a second positioning through hole corresponding to the first positioning through hole.

As a preferred scheme of the printed circuit board bearing jig, the driving assembly comprises a driving block, the driving block is provided with an avoidance groove, the second magnetic piece is arranged at the bottom of the avoidance groove, and when the driving assembly is close to the auxiliary bearing assembly, the auxiliary bearing assembly is arranged in the avoidance groove.

As a preferable scheme of the printed circuit board bearing jig, the bottom of the avoidance groove is provided with a mounting column, and the second magnetic part is arranged on the mounting column in a position-adjustable manner along the vertical direction.

As a preferred scheme of the printed circuit board bearing jig, the driving assembly comprises an absorption part, the main bearing part and the auxiliary bearing assembly are both provided with avoidance through holes, and the absorption part can absorb the printed circuit board when the driving assembly is close to the auxiliary bearing assembly.

As a preferable scheme of the printed circuit board bearing jig, the upper surface of the main bearing piece is provided with a placing groove, the placing groove is used for bearing the printed circuit board, and the first positioning through hole is arranged at the bottom of the placing groove.

The beneficial effects of the invention are as follows:

the invention is used for realizing the bearing of the printed circuit board by arranging the main bearing piece; the auxiliary bearing component is arranged below the main bearing component, and the driving component is arranged on one side, far away from the main bearing component, of the auxiliary bearing component, so that the driving component can drive the auxiliary bearing component to be far away from the main bearing component. Meanwhile, a first positioning through hole is formed in the main bearing component, a positioning column is arranged on the auxiliary bearing component, when the driving component does not drive the auxiliary bearing component to be far away from the main bearing component, the positioning column can penetrate through the first positioning through hole and is convexly arranged on the upper surface of the first positioning through hole, and the positioning of the printed circuit board is realized. When the driving assembly drives the auxiliary bearing assembly to be far away from the main bearing member, the positioning column does not extend out of the upper surface of the first positioning through hole any contact with the printed circuit board, and the printed circuit board bearing jig can be used for printing the printed circuit board. In order to realize the drive of drive assembly to supplementary bearing assembly, be provided with first magnetism spare on the supplementary bearing assembly, be provided with the second magnetism spare on the drive assembly, when drive assembly is close to supplementary bearing assembly, the second magnetism spare can attract with first magnetism spare, and then makes supplementary bearing assembly keep away from main bearing member. The printed circuit board bearing jig can realize bearing when the printed circuit board is printed, can realize bearing when the printed circuit board is bound, is beneficial to simplifying the production flow, and has lower cost and more accurate and reliable bearing.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following description will briefly explain the drawings needed in the description of the embodiments of the present invention, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the contents of the embodiments of the present invention and these drawings without inventive effort for those skilled in the art.

Fig. 1 is a schematic diagram of a driving assembly of a printed circuit board carrying jig according to an embodiment of the present invention not driving an auxiliary carrying assembly away from a main carrying member;

fig. 2 is a schematic diagram of a driving assembly of a printed circuit board carrying jig according to an embodiment of the present invention driving an auxiliary carrying assembly away from a main carrying member;

fig. 3 is an exploded view of a main carrier and an auxiliary carrier assembly of a printed circuit board carrier according to an embodiment of the present invention;

fig. 4 is an exploded view of an auxiliary carrier assembly of a pcb carrier provided in an embodiment of the present invention;

fig. 5 is a schematic diagram of a driving assembly of a printed circuit board carrier fixture according to an embodiment of the invention.

In the figure:

100. a main carrier; 110. a first positioning through hole; 120. a placement groove;

200. an auxiliary bearing assembly; 210. a first base plate; 211. a first magnetic member; 212. a mounting edge; 213. a guide hole; 214. a second positioning through hole; 220. a second base plate; 221. positioning columns;

300. a drive assembly; 310. a second magnetic member; 320. a driving block; 321. an avoidance groove; 322. a mounting column; 330. an absorbing member; 340. avoiding the through hole;

400. a reset assembly; 410. a guide post; 411. a boss; 420. and a reset piece.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Wherein the terms "first position" and "second position" are two different positions.

Unless specifically stated or limited otherwise, the terms "mounted," "connected," and "fixed" are to be construed broadly, and may be, for example, either fixed or removable; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present invention, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

As shown in fig. 1 to 5, the present embodiment provides a printed circuit board carrier, which includes a main carrier 100, an auxiliary carrier 200 and a driving assembly 300, wherein the main carrier 100 is used for carrying a printed circuit board, and a first positioning through hole 110 is provided on the main carrier 100; the auxiliary bearing assembly 200 is arranged below the main bearing member 100, a positioning column 221 and a first magnetic member 211 are arranged on the auxiliary bearing assembly 200, and the positioning column 221 can be arranged on the first positioning through hole 110 and extend out of the upper surface of the first positioning through hole 110; the driving assembly 300 is disposed below the auxiliary carrying assembly 200 in a position adjustable manner along the vertical direction, and the driving assembly 300 is provided with a second magnetic member 310, when the driving assembly 300 approaches the auxiliary carrying assembly 200, the second magnetic member 310 is magnetically attracted to the first magnetic member 211, so that the positioning post 221 does not extend out of the upper surface of the first positioning through hole 110.

By providing a main carrier 100 for carrying a printed circuit board; by providing the auxiliary carrier assembly 200 below the main carrier 100 and simultaneously providing the driving assembly 300 at a side of the auxiliary carrier assembly 200 remote from the main carrier 100, the driving assembly 300 is able to drive the auxiliary carrier assembly 200 away from the main carrier 100. Meanwhile, the main carrier 100 is provided with a first positioning through hole 110, and the auxiliary carrier 200 is provided with a positioning post 221. As shown in fig. 1, when the driving assembly 300 does not drive the auxiliary carrier assembly 200 away from the main carrier 100, the positioning posts 221 can penetrate through the first positioning through holes 110 and protrude from the upper surface of the first positioning through holes 110 for positioning the printed circuit board, and the printed circuit board carrier fixture can be used for bonding the printed circuit board. As shown in fig. 2, when the driving assembly 300 drives the auxiliary carrier assembly 200 away from the main carrier 100, the positioning posts 221 no longer extend out of the upper surface of the first positioning through holes 110, i.e. no contact with the pcb is made, and the pcb carrier can be used for printing the pcb. In order to drive the auxiliary carrying assembly 200 by the driving assembly 300, the auxiliary carrying assembly 200 is provided with a first magnetic member 211, and the driving assembly 300 is provided with a second magnetic member 310, and when the driving assembly 300 approaches the auxiliary carrying assembly 200, the second magnetic member 310 is magnetically attracted to the first magnetic member 211, so that the auxiliary carrying assembly 200 is far away from the main carrying assembly 100. The printed circuit board bearing jig can realize bearing when the printed circuit board is printed, can realize bearing when the printed circuit board is bound, is beneficial to simplifying the production flow, and has lower cost and more accurate and reliable bearing.

Illustratively, the first and second magnetic members 211, 310 may be configured as magnets of opposite magnetic properties such that when the drive assembly 300 is proximate to the auxiliary carrier assembly 200, the first and second magnetic members 211, 310 may attract each other to move the auxiliary carrier assembly 200 away from the main carrier 100.

Preferably, as shown in fig. 1 to 3, the printed circuit board carrier jig is provided with a reset assembly 400, and the reset assembly 400 is configured to drive the auxiliary carrier assembly 200 to approach the main carrier 100, so that the auxiliary carrier assembly 200 can be always and stably positioned to approach the main carrier 100 when the non-driving assembly 300 drives the auxiliary carrier assembly 200, so that the positioning posts 221 can be inserted into the first positioning through holes 110 and protrude from the upper surfaces of the first positioning through holes 110. It can be understood that when the driving assembly 300 drives the auxiliary carrying assembly 200, the driving assembly 300 is not close to the auxiliary carrying assembly 200, including the printed circuit board carrying jig, at the initial position; the driving assembly 300 is further included to drive the auxiliary bearing assembly 200 and then disengage from the auxiliary bearing assembly 200.

Specifically, the reset assembly 400 includes a guide pillar 410 and a reset member 420 sleeved on the guide pillar 410, one end of the guide pillar 410 is penetrated through the auxiliary bearing assembly 200 and connected with the main bearing member 100, the other end is provided with a boss 411, and the reset member 420 is abutted between the auxiliary bearing assembly 200 and the boss 411. When the driving assembly 300 drives the auxiliary bearing assembly 200, the elastic restoring force of the restoring member 420 is greater than the overall gravity of the auxiliary bearing assembly 200, so that the auxiliary bearing assembly 200 is completely attached to the main bearing assembly 100, and the positioning columns 221 are further ensured to be convexly arranged on the upper surface of the first positioning through hole 110. When the driving assembly 300 approaches the auxiliary carrying assembly 200, the first magnetic member 211 and the second magnetic member 310 attract each other, the auxiliary carrying assembly 200 gradually compresses the reset member 420 and further moves away from the main carrying assembly 100, so that the positioning post 221 is no longer protruding from the upper surface of the first positioning through hole 110.

In this embodiment, as shown in fig. 4, the auxiliary bearing assembly 200 includes a first bottom plate 210 and a second bottom plate 220 disposed below the first bottom plate 210, the first bottom plate 210 is provided with a mounting edge 212 extending out of the second bottom plate 220, the mounting edge 212 is provided with a guiding hole 213, and the guiding post 410 is disposed through the guiding hole 213. By providing the mounting edge 212, space is provided for the installation of the reset assembly 400. Illustratively, the guide post 410 is slidably coupled with the guide hole 213 and is screw-coupled with the main carrier 100, and may be used to adjust the reset speed of the auxiliary carrier assembly 200 by adjusting the screw coupling depth of the guide post 410 with the main carrier 100 or replacing the reset member 420 having a different elastic modulus.

Further, to make the stress of the auxiliary load bearing assembly 200 more uniform, both sides of the first bottom plate 210 are provided with mounting edges 212. In addition, the first magnetic members 211 are also disposed on the mounting sides 212, and each mounting side 212 is provided with a plurality of guide holes 213 and a plurality of first magnetic members 211. Correspondingly, the guide posts 410 and the second magnetic members 310 are correspondingly provided with a plurality of guide posts, which is beneficial to ensuring the reliability of the reset assembly 400 reset and the magnetic attraction between the first magnetic member 211 and the second magnetic member 310. In addition, the guide hole 213 may be spaced apart from the first magnetic member 211 to ensure balance between reset and magnetic attraction force.

Alternatively, the positioning columns 221 are disposed on the second bottom plate 220, and the first bottom plate 210 is provided with the second positioning through holes 214 corresponding to the first positioning through holes 110. By providing the second positioning through hole 214, the positioning column 221 can sequentially penetrate through the second positioning through hole 214 and the first positioning through hole 110, so that interference of the first bottom plate 210 to the positioning column 221 is avoided. In other embodiments, the positioning post 221 may also be disposed on the first bottom plate 210.

As an alternative to the printed circuit board bearing fixture, as shown in fig. 5, the driving assembly 300 includes a driving block 320, the driving block 320 is provided with a avoidance groove 321, the second magnetic member 310 is disposed at a bottom of the avoidance groove 321, and when the driving assembly 300 approaches to the auxiliary bearing assembly 200, the auxiliary bearing assembly 200 is disposed in the avoidance groove 321. By arranging the avoidance groove 321 on the driving block 320, the avoidance space of the driving block 320 for the auxiliary bearing assembly 200 is provided, and interference with the auxiliary bearing assembly 200 when the driving assembly 300 drives the auxiliary bearing assembly 200 is effectively avoided.

Optionally, in order to provide the second magnetic element 310 on the driving block 320, the mounting post 322 is provided at the bottom of the avoidance groove 321, the second magnetic element 310 is provided on the mounting post 322, and the provision of the mounting post 322 is beneficial to reducing the distance between the second magnetic element 310 and the first magnetic element 211 on the first bottom plate 210, so that the reliability of magnetic attraction between the first magnetic element 211 and the second magnetic element 310 can be ensured. Preferably, the second magnetic member 310 is disposed on the mounting post 322 with a position adjustable along a vertical direction, and by setting the second magnetic member 310 to be position adjustable along the vertical direction, a distance between the second magnetic member 310 and the first magnetic member 211 is further adjusted, and a magnetic attraction force between the first magnetic member 211 and the second magnetic member 310 is further adjusted.

In this embodiment, the driving assembly 300 includes an adsorbing member 330, and the main carrier 100 and the auxiliary carrier 200 are respectively provided with an avoiding through hole 340, and the adsorbing member 330 can adsorb the printed circuit board when the driving assembly 300 approaches the auxiliary carrier 200. By arranging the adsorbing member 330, the printed circuit board is adsorbed when the driving assembly 300 approaches the auxiliary bearing assembly 200 and the positioning post 221 is no longer convexly arranged on the upper surface of the first positioning through hole 110, so that the printed circuit board can be effectively ensured not to displace in the retracting process of the positioning post 221, and the bearing of the printed circuit board is more stable and accurate. The avoidance holes 340 can effectively avoid interference between the suction member 330 and the main carrier 100 and auxiliary carrier 200.

Further, the upper surface of the main carrier 100 is provided with a placement groove 120, the placement groove 120 is used for carrying a printed circuit board, and the placement groove 120 is arranged to enable the placement of the printed circuit board on the main carrier 100 to be more stable; the first positioning through holes 110 are disposed at the bottom of the placement groove 120, so that the first positioning through holes 110 can penetrate through the bottom of the placement groove 120 to position the printed circuit board.

The use process of the printed circuit board bearing jig is as follows: firstly, a printed circuit board bearing jig is placed at an initial position, namely, the auxiliary bearing assembly 200 is attached to the lower part of the main bearing member 100, and a positioning column 221 is convexly arranged on the upper surface of the first positioning through hole 110; the driving assembly 300 moves close to the auxiliary carrying assembly 200 until the first magnetic member 211 and the second magnetic member 310 attract each other to generate a magnetic force, and the magnetic force can drive the auxiliary carrying assembly 200 to move about 2mm towards a direction away from the main carrying assembly 100, so that the positioning columns 221 are no longer protruded on the upper surface of the first positioning through holes 110 for printing on the printed circuit board; after printing, the driving assembly 300 is far away from the auxiliary bearing assembly 200, the first magnetic element 211 and the second magnetic element 310 are separated from magnetic attraction, and the auxiliary bearing assembly 200 is restored to the position where the positioning post 221 is convexly arranged at the first positioning through hole 110, so as to position the printed current board, and achieve bonding of the printed circuit board. The process does not need to replace the bearing jig, the production process is simplified, the cost is lower, and the efficiency is higher.

The foregoing is merely exemplary of the present invention, and those skilled in the art should not be considered as limiting the invention, since modifications may be made in the specific embodiments and application scope of the invention in light of the teachings of the present invention.

Claims (10)

1. The utility model provides a printed circuit board bears tool which characterized in that includes:

a main carrier (100) for carrying a printed circuit board, wherein a first positioning through hole (110) is arranged on the main carrier (100);

the auxiliary bearing assembly (200) is arranged below the main bearing member (100), a positioning column (221) and a first magnetic member (211) are arranged on the auxiliary bearing assembly (200), and the positioning column (221) can be arranged on the first positioning through hole (110) and extend out of the upper surface of the first positioning through hole (110);

the driving assembly (300) is arranged below the auxiliary bearing assembly (200) in a position adjustable manner along the vertical direction, a second magnetic piece (310) is arranged on the driving assembly (300), and when the driving assembly (300) is close to the auxiliary bearing assembly (200), the second magnetic piece (310) and the first magnetic piece (211) are magnetically attracted, so that the positioning column (221) does not extend out of the upper surface of the first positioning through hole (110).

2. The printed circuit board carrier jig according to claim 1, characterized in that the printed circuit board carrier jig is provided with a reset assembly (400), the reset assembly (400) being configured to drive the auxiliary carrier assembly (200) close to the main carrier (100).

3. The printed circuit board bearing jig according to claim 2, wherein the resetting component (400) comprises a guide pillar (410) and a resetting piece (420) sleeved on the guide pillar (410), one end of the guide pillar (410) is arranged on the auxiliary bearing component (200) in a penetrating manner and is connected with the main bearing piece (100), the other end of the guide pillar is provided with a boss (411), and the resetting piece (420) is abutted between the auxiliary bearing component (200) and the boss (411).

4. A printed circuit board bearing jig according to claim 3, characterized in that the auxiliary bearing assembly (200) comprises a first bottom plate (210) and a second bottom plate (220) arranged below the first bottom plate (210), the first bottom plate (210) is provided with a mounting edge (212) extending out of the second bottom plate (220), the mounting edge (212) is provided with a guide hole (213), and the guide post (410) penetrates through the guide hole (213).

5. The printed circuit board carrying jig according to claim 4, wherein both sides of the first base plate (210) are provided with the mounting sides (212), the first magnetic members (211) are disposed on the mounting sides (212), and each mounting side (212) is provided with a plurality of guide holes (213) and a plurality of first magnetic members (211).

6. The printed circuit board carrier jig according to claim 4, wherein the positioning posts (221) are disposed on the second bottom plate (220), and the first bottom plate (210) is provided with second positioning through holes (214) corresponding to the first positioning through holes (110).

7. The printed circuit board bearing jig according to claim 1, wherein the driving assembly (300) comprises a driving block (320), the driving block (320) is provided with an avoidance groove (321), the second magnetic member (310) is disposed at the bottom of the avoidance groove (321), and when the driving assembly (300) approaches the auxiliary bearing assembly (200), the auxiliary bearing assembly (200) is disposed in the avoidance groove (321).

8. The printed circuit board bearing jig according to claim 7, wherein a mounting post (322) is provided at a bottom of the avoidance groove (321), and the second magnetic member (310) is position-adjustably provided at the mounting post (322) in a vertical direction.

9. The jig according to claim 1, wherein the driving assembly (300) comprises an adsorption member (330), the main carrier (100) and the auxiliary carrier (200) are provided with avoiding through holes (340), and the adsorption member (330) can adsorb the printed circuit board when the driving assembly (300) approaches the auxiliary carrier (200).

10. The printed circuit board bearing jig according to claim 1, wherein a placement groove (120) is provided on an upper surface of the main bearing member (100), the placement groove (120) is used for bearing the printed circuit board, and the first positioning through hole (110) is provided at a groove bottom of the placement groove (120).