CN213054462U - Multi-station FPC product bearing structure - Google Patents

Abstract

The utility model relates to a multistation bears FPC product structure, it includes: the supporting assembly comprises a bottom plate, and a first through hole is formed in the middle of the bottom plate; the rotating assembly comprises a rotating disc and a driving unit, the rotating disc is rotatably arranged in the first through hole, the driving unit is arranged below the rotating disc and is used for driving the rotating disc to rotate, and the rotating disc is provided with a second through hole formed in the middle of the rotating disc and a plurality of machining positions symmetrically formed on the upper surface of the rotating disc; and the bearing component comprises a supporting part arranged on the processing position, and a first bearing plate and a second bearing plate which are embedded on the supporting part and used for bearing two end parts of the FPC product. The utility model discloses the multistation bears FPC product structure can show the efficiency of software testing that improves the product, and the skew of position can not take place for the product in the testing process, makes the test result more accurate, practices thrift the cost.

Description

Multi-station FPC product bearing structure

Technical Field

The utility model belongs to the machining technology field, concretely relates to multistation bears FPC product structure.

Background

At present, in a common FPC testing mode, a product is manually placed on a testing machine, the product is taken out after the testing is finished, then another product is placed for testing, and the like; the prior art has low processing efficiency and wastes time; if in order to guarantee machining efficiency, then need purchase many test board, and still will be equipped with more operators, the cost is wasted, and because the performance influence of FPC product self needs a tool in order to bear FPC, makes it the deviation of position can not appear in the test procedure, if do not assist the tool to assist, the inaccurate condition emergence of test result can appear, and then can influence follow-up assembly.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a multistation bears FPC product structure for overcoming the not enough of prior art.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a multistation bears FPC product structure, it includes:

the supporting assembly comprises a bottom plate, and a first through hole is formed in the middle of the bottom plate;

the rotating assembly comprises a rotating disc and a driving unit, the rotating disc is rotatably arranged in the first through hole, the driving unit is arranged below the rotating disc and is used for driving the rotating disc to rotate, and the rotating disc is provided with a second through hole formed in the middle of the rotating disc and a plurality of machining positions symmetrically formed on the upper surface of the rotating disc;

and the bearing component comprises a supporting part arranged on the processing position, and a first bearing plate and a second bearing plate which are embedded on the supporting part and used for bearing two end parts of the FPC product.

Further, the supporting component further comprises a first supporting plate symmetrically arranged on the lower surface of the bottom plate, a second supporting plate symmetrically arranged on the inner side of the first supporting plate and a connecting plate connected with the second supporting plate, and a third through hole is formed in the middle of the connecting plate.

Furthermore, the rotating assembly further comprises a switching part which is arranged on the lower surface of the base plate and used for connecting the base plate and the driving unit, and the driving unit is a rotating cylinder.

Furthermore, the supporting part comprises a third supporting plate and a fourth supporting plate which are arranged on the processing position in a stacked mode, and a first containing space used for containing the first bearing plate and the second bearing plate is formed in the third supporting plate.

Furthermore, the bearing assembly further comprises a first groove, a stopping part, a notch, a lug, a turnover plate and a second accommodating space, wherein the first groove is formed in the first bearing plate and used for placing the end part of the FPC product, the stopping part is formed on the periphery of the first groove and used for stopping the end part of the FPC product, the notch is formed in one side of the first bearing plate, the lug is symmetrically installed at the notch, the turnover plate is pivotally connected to the lug, and the second accommodating space is formed in the turnover plate.

Furthermore, a second groove for bearing the other end of the FPC product is formed in the second bearing plate.

Furthermore, the rotating assembly further comprises an oil buffer arranged on one opposite side of the second supporting plate and an oil pressure stop block arranged on the lower surface of the rotary disc and matched with the oil buffer for use.

Further, switching portion is established including wearing to establish pivot, cover in the second through-hole are established pivot one end just is used for connecting the first ring portion and the cover of carousel are established the pivot other end is used for connecting revolving cylinder's second ring portion.

Further, the stopper portion includes an arc portion formed on a periphery of the first groove and a plurality of protrusions.

Further, when the turnover plate is turned to be attached to the first bearing plate, the protruding portion is accommodated in the second accommodating space.

Because of the application of the technical scheme, compared with the prior art, the utility model has the following advantages: the multi-station FPC product bearing structure of the utility model drives the rotary table to rotate through the rotary cylinder, thereby realizing the multi-station coordination work; and the FPC product to be tested is placed on the bearing assembly, and the position of the FPC product cannot deviate in the testing process, so that the subsequent testing is greatly facilitated, the testing efficiency is improved, and the cost is saved.

Drawings

FIG. 1 is a schematic structural view of a multi-station FPC product structure of the present invention;

FIG. 2 is a schematic structural view of the present invention with the load bearing assembly removed;

FIG. 3 is a schematic structural view of the present invention with the turntable removed;

FIG. 4 is a schematic structural view of the load-bearing assembly of the present invention;

fig. 5 is a schematic structural view of the supporting portion of the present invention;

FIG. 6 is a schematic structural view of the first carrier plate of the present invention;

FIG. 7 is a schematic structural view of a second carrier plate according to the present invention;

FIG. 8 is a schematic structural view of the turnover plate of the present invention when it is horizontal;

FIG. 9 is a schematic structural view of the turnover plate of the present invention when it is upright;

fig. 10 is a schematic structural view of the adapter of the present invention;

fig. 11 is a lower surface view of the bottom plate of the present invention;

fig. 12 is a diagram of the position relationship between the connection plate and the second support plate according to the present invention;

fig. 13 is a schematic view of the lower surface structure of the turntable of the present invention;

description of reference numerals:

1. a support assembly; 11. a base plate; 111. a first through hole; 12. a first support plate; 13. a second support plate; 14. a connecting plate; 141. a third through hole;

2. a rotating assembly; 21. a turntable; 211. a second through hole; 212. a machining position; 22. a switching part; 221. a rotating shaft; 222. A first ring portion; 223. a second ring portion; 23. a rotating cylinder; 24. a hydraulic shock absorber; 25. an oil pressure stop block;

3. a load bearing assembly; 31. a support portion; 311. a third support plate; 3111. a first accommodating space; 312. a fourth support plate; 32. A first bearing plate; 321. a first groove; 322. a stopper portion; 3221. an arc-shaped portion; 3222. a boss portion; 323. a notch; 324. A lug; 325. a turnover plate; 3251. a second accommodating space; 33. a second carrier plate; 331. a second groove.

Detailed Description

The invention will be further described with reference to examples of embodiments shown in the drawings.

As shown in fig. 1 to 13, the multi-station FPC product carrying structure is used for carrying the FPC product to be tested and completing the conversion of the stations, so as to improve the testing efficiency (i.e., the multi-station FPC product carrying structure is correspondingly installed on the automatic testing machine for carrying out the rotation of the stations on the product placed on the working position thereof, so as to realize that a new product is placed on another working position while the product is processed, thereby improving the processing efficiency). The device mainly comprises a supporting component 1, a rotating component 2, a bearing component 3 and the like.

Wherein the supporting component 1 mainly plays a role of bearing, and mainly comprises a bottom plate 11, a first supporting plate 12, a second supporting plate 13, a connecting plate 14 and the like. The bottom plate 11 is usually installed on the test machine (the bottom plate 11 is a rectangular metal plate, the specific shape is not the protection key of the utility model, the material is selected from stainless steel, the installation of the bottom plate 11 can be realized by the screw fastening mode; in this embodiment, the first through hole 111 has been seted up at the middle part of the bottom plate 11, the first through hole 111 is in a round shape, and the processing can be realized by the drilling process). The first supporting plate 12 has two, and they symmetry is installed at bottom plate 11 lower surface (first supporting plate 12 is the rectangle metal sheet, and the material chooses for use the stainless steel, accessible welding or screw fastening's mode realization). Second backup pad 13 has two, and their symmetry is installed inboard first backup pad 12 (second backup pad 13 is the rectangle metal sheet, and the stainless steel is chooseed for use to the material, and its concrete shape is not the utility model discloses a protection is key, and installation is accomplished to accessible welding or screw-up's mode). As shown in fig. 12, the connecting plate 14 is connected to the two second supporting plates 13 (the connecting plate 14 is a rectangular metal plate made of stainless steel, and the connecting plate 14 can be connected to the two second supporting plates 13 by welding or screw fastening, in this embodiment, a third through hole 141 is formed in the middle of the connecting plate 14, and the third through hole 141 is circular and can be realized by a drilling process).

The rotating assembly 2 includes a turntable 21, an adapter 22, a drive unit, and the like. The rotating disc 21 is rotatably installed in the first through hole 111 (the rotating disc 21 is a circular metal plate made of stainless steel, the diameter of the rotating disc 21 is slightly smaller than that of the first through hole 111; in this embodiment, the middle of the rotating disc 21 is provided with a second through hole 211, the second through hole 211 is circular and can be realized by a drilling process, the rotating disc 21 is symmetrically provided with two processing positions 212 for installing the bearing component 3, and the shape of the processing positions 212 is determined according to the shape of the bearing component). The adapting portion 22 is installed below the turntable 21 and is used for driving the turntable 21 to rotate (as shown in fig. 10, in this embodiment, the adapting portion 22 includes a rotating shaft 221, a first ring portion 222, a second ring portion 223, and the like, the rotating shaft 221 is inserted into the second through hole 211, the rotating shaft 221 is made of cylindrical metal, the first ring portion 222 is sleeved on the rotating shaft 221 and connected with the lower surface of the turntable 21, the first ring portion 222 is concentric ring-shaped, the first ring portion 222 is installed on the lower surface of the turntable 21 in a screw fastening manner, the second ring portion 223 is sleeved on the other end portion of the rotating shaft 221, and the second ring portion 223 is concentric ring-. The driving unit is a rotary cylinder 23 (the rotary cylinder 23 is usually a conventional one, such as model MSQB; in this embodiment, the cylinder body of the rotary cylinder 23 is mounted on the lower surface of the connecting plate 15 by means of screw fastening, and the rotary part of the rotary cylinder 23 passes through the third through hole 141 of the connecting plate 14 and is connected with the second ring part 223).

Further, the rotating unit 2 further includes an oil buffer 24, an oil stopper 25, and the like. The hydraulic buffers 24 are two in number and are installed on the opposite sides of the second support plate 13 (the hydraulic buffers 24 may be installed on the second support plate 13 by means of screws, as long as they are generally available in the AC series). The oil pressure stop 25 is fixed on the lower surface of the rotary table 21 and is matched with the oil pressure buffers 24 for use (the oil pressure stop 25 is a rectangular metal block and can be installed in a screw fastening or welding mode; in the rotating process of the rotary table 21, the oil pressure stop 25 rotates along with the rotary table 21; in the embodiment, the rotary table 21 rotates forwards and backwards by 180 degrees, and the oil pressure stop 25 rotates between the two oil pressure buffers 24 so as to reduce the vibration of the whole structure in the rotating process).

Further, when the rotating shaft 221 passes through the second through hole 211 and extends to the upper surface of the rotating disc 21, the first ring portion 222 is attached to the lower surface of the rotating disc 21 for subsequent locking.

The carrier assembly 3 is installed at the processing position 212, and mainly includes a support portion 31, a first carrier plate 32, a second carrier plate 33, and the like. The support portion 31 mainly includes a third support plate 311, a fourth support plate 312, and the like. The fourth supporting plate 312 is mounted on the processing position 212 (the fourth supporting plate 312 is a rectangular metal plate, and the material thereof is stainless steel). The third supporting plate 311 is mounted on the fourth supporting plate 312 (the third supporting plate 311 is a rectangular metal plate, the material of the third supporting plate 311 is stainless steel, and the third supporting plate 311 can be mounted on the upper surface of the fourth supporting plate 312 by fastening screws; in this embodiment, two first receiving spaces 3111 with different shapes are formed on the third supporting plate 311, that is, the third supporting plate 311 is formed by inwardly forming grooves).

The first bearing plate 32 is embedded on the third supporting plate 311 and is used for bearing the end part of the FPC product; it mainly comprises a first groove 321, a stopping part 322, a notch 323, a lug 324, a turnover plate 325 and the like. The first groove 321 is formed on the first carrier 32 for carrying an end portion of an FPC product (the thickness of the first groove 321 is the same as that of the FPC product to be tested). The stopping portion 322 is disposed around the first groove 321 for stopping an end portion of the FPC product received in the first groove 321 (the stopping portion 322 includes three sets of an arc portion 3221 and a protrusion portion 3222, and the rectangular protrusion portion 3222). The notch 323 is formed on one side of the first carrier plate 32 (the notch 323 is rectangular). As shown in fig. 8, there are two lugs 324, which are symmetrically installed at the notch 323 of the first loading plate 32 (the lugs 324 are rectangular metal blocks, and can be installed by welding). The flipping board 325 is pivotally mounted on the protrusion 324 (the flipping board 325 is a rectangular metal board made of stainless steel, and a hole groove is formed at a position opposite to the protrusion 324 and the flipping board 325, and a rotating shaft is mounted in the hole groove; in this embodiment, the flipping board 325 is provided with a second accommodating space 3251, the second accommodating space 3251 is a rectangular groove, and when the flipping board 325 is flipped to be attached to the first loading board 32, the protrusion 3222 is accommodated in the second accommodating space 3251).

The second carrier plate 33 is embedded on the third supporting plate 311 in cooperation with the first carrier plate 32, and is used for carrying the other end of the FPC product. As shown in fig. 7, it mainly includes a second recess 331 opened on an upper surface thereof. The second recess 331 is formed on the second carrier plate 33 for carrying the other end of the FPC product (the thickness of the second recess 331 is the same as the thickness of the FPC product to be tested).

The utility model discloses multistation bears FPC product structure when concrete work, turns over the returning face plate 325 and turns up certain angle, and the manual work is put FPC product both ends that await measuring respectively on first loading board 32 and second loading board 33, resets returning face plate 325, and the bellying 3222 that is used for backstop FPC product tip this moment is held in the second accommodation space 3251 of returning face plate 325; the rotary table 21 is driven by the rotary cylinder 23 to rotate 180 degrees, and meanwhile, the oil pressure stop 25 is in contact with the oil buffer 24 to reduce the vibration of the whole structure; at this moment, the carrier assembly 3 placed with the product rotates to the test position to be tested, the vacant carrier assembly 3 is rotated out, another product to be tested can be placed in the vacant carrier assembly 3 manually, the last product is processed and finished, the steps are repeated, the rotary cylinder 23 drives the rotary table 21 to rotate reversely by 180 degrees, the untested product is rotated to the test position to be tested, the tested product is rotated out, the tested product is taken away manually, and new products can be placed.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (10)

1. The utility model provides a multistation bears FPC product structure which characterized in that, it includes:

the supporting component (1), the supporting component (1) comprises a bottom plate (11), and a first through hole (111) is formed in the middle of the bottom plate (11);

the rotating assembly (2) comprises a rotating disc (21) which is rotatably arranged in the first through hole (111) and a driving unit which is arranged below the rotating disc (21) and is used for driving the rotating disc to rotate, wherein the rotating disc (21) is provided with a second through hole (211) which is formed in the middle of the rotating disc and a plurality of processing positions (212) which are symmetrically formed on the upper surface of the rotating disc;

the bearing component (3) comprises a supporting part (31) arranged on the processing position (212), and a first bearing plate (32) and a second bearing plate (33) which are embedded on the supporting part (31) and used for bearing two end parts of the FPC product.

2. The multi-station FPC product bearing structure of claim 1, wherein: the supporting component (1) further comprises a first supporting plate (12) symmetrically arranged on the lower surface of the bottom plate (11), a second supporting plate (13) symmetrically arranged on the inner side of the first supporting plate (12) and a connecting plate (14) connected with the second supporting plate (13), and a third through hole (141) is formed in the middle of the connecting plate (14).

3. The multi-station FPC product bearing structure of claim 1, wherein: the rotating assembly (2) further comprises a switching part (22) which is arranged on the lower surface of the base plate (11) and used for connecting the base plate (11) and the driving unit, and the driving unit is a rotating cylinder (23).

4. The multi-station FPC product bearing structure of claim 1, wherein: the supporting portion (31) comprises a third supporting plate (311) and a fourth supporting plate (312) which are arranged on the machining position (212) in a stacked mode, and a first containing space (3111) for containing the first bearing plate (32) and the second bearing plate (33) is formed in the third supporting plate (311).

5. The multi-station FPC product bearing structure of claim 1, wherein: the bearing component (3) further comprises a first groove (321) which is formed in the first bearing plate (32) and used for placing the end part of the FPC product, a stopping part (322) which is formed on the periphery of the first groove (321) and used for stopping the end part of the FPC product, a notch (323) which is formed in one side of the first bearing plate (32), lugs (324) which are symmetrically installed at the notch (323), a turnover plate (325) which is pivotally connected to the lugs (324) and a second containing space (3251) which is formed in the turnover plate (325).

6. The multi-station FPC product bearing structure of claim 1, wherein: and a second groove (331) used for bearing the other end part of the FPC product is arranged on the second bearing plate (33).

7. The multi-station FPC product bearing structure of claim 2, wherein: the rotating assembly (2) further comprises an oil pressure buffer (24) arranged on one opposite side of the second supporting plate (13) and an oil pressure stop block (25) arranged on the lower surface of the rotary disc (21) and matched with the oil pressure buffer (24) for use.

8. The multi-station FPC product bearing structure of claim 3, wherein: switching portion (22) is established including wearing to establish pivot (221), the cover in second through-hole (211) is established pivot (221) one end just is used for connecting first ring portion (222) and the cover of carousel (21) are established pivot (221) other end is used for connecting second ring portion (223) of revolving cylinder (23).

9. The multi-station FPC product bearing structure of claim 5, wherein: the stopper portion (322) includes an arc portion (3221) formed on a circumference of the first groove (321) and a plurality of protrusions (3222).

10. The multi-station FPC product bearing structure of claim 9, wherein: when the turnover plate (325) is turned to be attached to the first bearing plate (32), the protrusion (3222) is accommodated in the second accommodating space (3251).

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