CN112495823A - Detection structure and testing device - Google Patents

Abstract

The invention discloses a detection structure and a test device, and belongs to the technical field of electronic product test equipment. The testing device comprises a testing structure, the testing structure comprises a mechanical arm and a testing mechanism, the mechanical arm comprises a mechanical arm and a material taking mechanism, the material taking mechanism comprises a first connecting part, a first suction nozzle component and a second suction nozzle component, the first connecting part is connected to the output end of the mechanical arm in a lifting mode, the first suction nozzle component and the second suction nozzle component are respectively connected to the first connecting part in a lifting mode, the first suction nozzle component is used for sucking a main body of a product, and the second suction nozzle component is used for sucking a flat cable of the product; the testing mechanism comprises a testing platform and a second pressing assembly, the testing platform is provided with a testing groove, and a probe module for conducting with a product is arranged in the testing groove; the second pressing component can press the product in the test slot, and the manipulator can place the product in the test slot. The invention improves the positioning effect of the product, thereby improving the testing efficiency of the product.

Description

Detection structure and testing device

Technical Field

The invention relates to the technical field of electronic product testing equipment, in particular to a detection structure and a testing device.

Background

The flat cable is a flexible circuit board for connecting two electronic device modules, and in order to ensure that the appearance of a main body of a product is free from defects and that each line in the flat cable of the product is a path rather than an open path, a power-on test needs to be performed on the product, so that the product is lighted up and whether the product has defects or not is observed. When the product flat cable is tested, one end of the flat cable is connected with the main body of the product, and if the flat cable is discharged, the positions of the flat cable and the test groove are deviated, so that the test result is inaccurate, and even the flat cable is damaged.

Disclosure of Invention

One objective of the present invention is to provide a detection structure, which can reduce damage to a product and improve the testing efficiency of the product.

Another objective of the present invention is to provide a testing apparatus, which improves the accuracy of product testing.

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

a detection structure comprises a manipulator and a testing mechanism, wherein the manipulator comprises a mechanical arm and a material taking mechanism, the material taking mechanism comprises a first connecting part, a first suction nozzle assembly and a second suction nozzle assembly, the first connecting part is connected to the output end of the mechanical arm in a lifting mode, the first suction nozzle assembly and the second suction nozzle assembly are respectively connected to the first connecting part in a lifting mode, the first suction nozzle assembly is used for sucking a main body of a product, and the second suction nozzle assembly is used for sucking a flat cable of the product; the testing mechanism comprises a testing platform and a second pressing assembly, the testing platform is provided with a testing groove, and a probe module which is used for being conducted with the product is arranged in the testing groove; the second pressing assembly is configured to press the product within the test slot, and the manipulator is configured to place the product within the test slot.

Optionally, the first nozzle assembly includes a first elastic buffer portion and a first nozzle, a top end of the first elastic buffer portion is connected to the first connection portion, a bottom end of the first elastic buffer portion is connected to the first nozzle, and the first nozzle is slidably connected to the first connection portion through a first connection member.

Optionally, the second nozzle assembly includes a first driving portion and a second nozzle, the second nozzle is slidably connected to the first connecting portion, and the first driving portion is connected to the first connecting portion and can drive the second nozzle to ascend and descend along the first connecting portion.

Optionally, the second pressing assembly comprises:

a second connecting portion;

a third driving part connected to the second connecting part;

the fourth driving part is connected to the output end of the third driving part, and the third driving part can drive the fourth driving part to approach or leave the test slot along the horizontal direction; and

the second pressing piece is connected to the output end of the fourth driving portion, and the fourth driving portion can drive the second pressing piece to approach or leave the test slot along the vertical direction.

Optionally, the method further comprises:

the first CCD camera is connected to the execution end of the mechanical arm; and

and the second CCD camera can photograph the product when the manipulator conveys the product to the testing mechanism.

Optionally, the testing mechanism further includes a light shield, the testing platform and the second pressing assembly are both disposed in the light shield, and the light shield is used for blocking an external light source.

Optionally, the light shield has a light shield door, and the light shield door is connected to a side wall of the light shield in a lifting manner.

Optionally, the test device further comprises a discharging platform, and the manipulator can convey the tested product to the discharging platform.

Optionally, the blanking platform comprises:

the manipulator can convey the tested good products to the good product blanking platform; and

and the manipulator can convey the tested defective products to the defective product blanking platform.

A testing device comprises the detection structure.

The invention has the beneficial effects that:

when the detection structure takes materials through the manipulator, the first suction nozzle assembly and the second suction nozzle assembly descend along the first connecting part, when the first suction nozzle assembly absorbs the main part of a product, the second suction nozzle assembly is at a certain distance from the product, after the first suction nozzle assembly absorbs the main part of the product, the second suction nozzle assembly takes materials again, through the arrangement of the first suction nozzle assembly and the second suction nozzle assembly, the material taking process of the product can be divided into two steps, the situation that a material taking mechanism cannot absorb the main part of the product and a flat cable at the same time is reduced, the situation that the flat cable is inaccurately positioned due to warping or bending is reduced, the positioning effect of the product is improved, and the testing efficiency of the product is improved;

the testing device comprises the detection structure, and the product accuracy of the test can be improved.

Drawings

FIG. 1 is a schematic perspective view of a testing apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic top view of a testing apparatus according to an embodiment of the present invention;

FIG. 3 is a schematic perspective view of a detection structure according to an embodiment of the present invention;

fig. 4 is a schematic perspective view of a material taking mechanism and a first CCD camera according to an embodiment of the present invention;

FIG. 5 is a schematic perspective view of a two-station take off mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic perspective view of a material removal mechanism for a station according to an embodiment of the present invention;

FIG. 7 is a schematic perspective view of a testing mechanism with a light shield removed according to an embodiment of the present invention;

FIG. 8 is a schematic perspective view of a test platform according to an embodiment of the present invention;

fig. 9 is a schematic perspective view of a light shield according to an embodiment of the present invention;

FIG. 10 is a schematic perspective view of a second pressing assembly according to an embodiment of the present invention;

fig. 11 is a schematic perspective view of a storage platform according to an embodiment of the present invention;

FIG. 12 is a schematic perspective view of a positioning structure provided in accordance with an embodiment of the present invention;

fig. 13 is a schematic perspective view of a defective blanking platform according to an embodiment of the present invention.

In the figure:

1. a manipulator; 11. a mechanical arm; 12. a material taking mechanism; 121. a first connection portion; 1211. a first connecting plate; 1212. a second connecting plate; 122. a first nozzle assembly; 1221. a first elastic buffer portion; 1222. a first suction nozzle; 1223. a first connecting member; 1224. a first pressure feedback element; 123. a second nozzle assembly; 1231. a first driving section; 1232. a second suction nozzle; 124. a fifth driving section;

2. a material storage platform; 21. a storage tank; 211. detecting the through hole; 22. a detection element;

3. a positioning structure; 31. positioning the platform; 311. positioning a groove; 32. a first pressing assembly; 321. a second driving section; 322. a first pressing member; 33. a pilot assembly; 331. a sixth driving section; 332. a guide block;

4. a testing mechanism; 41. a light shield; 411. a light-shielding door; 412. a seventh driving section; 42. a test platform; 421. a test slot; 422. a probe module; 43. a second pressing assembly; 431. a second connecting portion; 432. a third driving section; 433. a fourth driving section; 434. a second pressing member; 435. a second elastic buffer part; 436. a second connecting member; 437. a second pressure feedback element; 44. a static eliminator; 45. detecting a camera;

5. a blanking platform; 51. a good product blanking platform; 52. a defective product blanking platform; 521. a defective product bearing platform; 522. removing the component; 5221. an eighth driving section; 5222. a ninth driving section; 5223. a third connecting member; 52231. a third connecting plate; 52232. a fourth connecting plate; 5224. a fifth connecting plate;

6. a first CCD camera;

7. a second CCD camera;

8. and (7) mounting the platform.

Detailed Description

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" 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 expressly stated or limited otherwise, the terms "mounted," "connected," and "secured" are to be construed broadly and encompass, for example, both fixed and removable connections; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may include the first feature being in direct contact with the second feature, or may include the first feature being in direct contact with the second feature but being in contact with the second feature by another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The technical solution of the present invention is further explained by the following embodiments with reference to the attached fig. 1-12.

The embodiment provides a testing device, as shown in fig. 1 and fig. 2, the testing device includes a detection structure, a positioning structure 3, and a storage platform 2. As shown in fig. 3, 4, 7 and 8, the detection structure includes a manipulator 1 and a testing mechanism 4, the manipulator 1 includes a manipulator 11 and a material taking mechanism 12, the material taking mechanism 12 includes a first connecting portion 121, a first nozzle assembly 122 and a second nozzle assembly 123, the first connecting portion 121 is connected to an output end of the manipulator 11 in a lifting manner, the first nozzle assembly 122 and the second nozzle assembly 123 are respectively connected to the first connecting portion 121 in a lifting manner, the first nozzle assembly 122 is used for sucking a main body of a product, and the second nozzle assembly 123 is used for sucking a flat cable of the product. The testing mechanism 4 comprises a testing platform 42 and a second pressing assembly 43, the testing platform 42 is provided with a testing groove 421, and a probe module 422 for conducting with a product is arranged in the testing groove 421; the second pressing assembly 43 is capable of pressing a product in the test slot 421, and the manipulator 1 is capable of placing the product in the test slot 421.

When the manipulator 1 in this embodiment takes materials, the first nozzle assembly 122 and the second nozzle assembly 123 descend along the first connecting portion 121, when the first nozzle assembly 122 absorbs the main body portion of the product, the second nozzle assembly 123 is at a certain distance from the product, after the first nozzle assembly 122 absorbs the main body of the product, the second nozzle assembly 123 takes materials again, through the arrangement of the first nozzle assembly 122 and the second nozzle assembly 123, the material taking process of the product can be divided into two steps, the situation that the material taking mechanism cannot absorb the main body of the product and the flat cable at the same time is reduced, the situation that the flat cable is warped or bent to cause inaccurate positioning is reduced, the positioning effect of the product is improved, and the testing efficiency of the product is improved.

In detail, when the second pressing component 43 presses the product in the test slot 421, the flat cable can communicate with the probe module 422, so as to light the product. Further, a detection camera 45 is arranged above the test platform 42, and the lighted product is photographed by the detection camera 45, so that whether the surface of the product has flaws or not is observed.

Further, as shown in fig. 1 and 11, the storage platform 2 is disposed at a predetermined position, and the storage platform 2 has a plurality of storage slots 21 for storing the products to be detected. The robot 1 is able to transport the products inside the magazine 21 to the positioning structure 3, the positioning structure 3 being configured to guide the products. The manipulator 1 is able to transport the products, which are aligned by the positioning structure 3, to the testing mechanism 4. In this embodiment, carry the product of saving in the stock chest 21 in storage platform 2 to location structure 3 through manipulator 1, manipulator 1 gets and to carry out a location to the product after the material, can carry out the secondary location to the product through location structure 3, has improved the positioning accuracy of product, makes placing in accredited testing organization 4 that the product can be accurate, carries out accurate test to the product, reduces because the inaccurate damage that leads to the fact the product in location.

In order to further improve the efficiency of testing to the product, manipulator 1 can set up 2 at least material taking stations, makes manipulator 1 once can get 2 at least products, and manipulator 1 in this embodiment preferably is provided with 2 material taking stations, and 2 material taking station intervals set up. Of course, the skilled person can make other number and position layouts according to the needs, and the layout is not limited herein. Correspondingly, each storage platform 2 includes at least 2 storage troughs 21 therein, the storage troughs 21 are arranged in even or odd rows, and preferably, the arrangement of the storage troughs 21 of each storage platform 2 in this embodiment corresponds to the position of the material taking station of the manipulator 1, so that each material taking station of the manipulator 1 can take materials at the same time. Optionally, each positioning structure 3 includes at least 2 positioning stations, the number and the position of the positioning stations correspond to those of the material taking stations, and preferably, 2 positioning stations are provided in this embodiment. Similarly, this embodiment is provided with 2 at least test station, and the overall arrangement of test station's position is corresponding with the material taking station, and the quantity of test station can be corresponding with the material taking station or be more than the material taking station.

In order to make the overall structure of the testing device in this embodiment more compact, as shown in fig. 1, the testing device in this embodiment further includes a mounting platform 8, and the detection structure, the storage platform 2 and the positioning structure 3 are all disposed at the top of the mounting platform 8.

Specifically, as shown in fig. 11, the storage platform 2 has a plurality of storage troughs 21 arranged in sequence, the bottom of each storage trough 21 is provided with a detection through hole 211, the bottom of each detection through hole 211 is provided with a detection element 22, the detection element 22 is configured to detect whether a product is placed in each storage trough 21, if a product is placed in each storage trough 21, the manipulator 1 can take the product, if no product is in each storage trough 21, the manipulator 1 can move to the next storage trough 21 to take the product, if no product is in all the storage troughs 21, the material can be timely supplemented, and in an optional embodiment, the detection element 22 is a photoelectric sensor. The specific form of the detecting element 22 can be selected by those skilled in the art as needed, and is not limited herein.

As shown in fig. 4 to 6, the first connecting portion 121 is slidably connected to the output end of the robot arm 11, the first connecting portion 121 is driven to move up and down by the fifth driving portion 124, the fifth driving portion 124 is connected to the output end of the robot arm 11, and the first connecting portion 121 is connected to the executing end of the fifth driving portion 124. In some alternative embodiments, the fifth driving portion 124 is an air cylinder, and of course, the fifth driving portion 124 can drive the first connecting portion 121 to move up and down, and the specific form thereof is not limited herein. In some alternative embodiments, the first connection portion 121 includes a first connection plate 1211 and a second connection plate 1212, the first connection plate 1211 is connected to the output end of the robot arm 11 through a slide rail, the second connection plate 1212 is vertically connected to the first connection plate 1211, and the first nozzle assembly 122 and the second nozzle assembly 123 are respectively disposed at two sides of the second connection plate 1212.

In order to further reduce damage to the product caused by the robot arm 1 during the material taking process, as shown in fig. 5 and 6, the first nozzle assembly 122 includes a first elastic buffer 1221 and a first nozzle 1222, a top end of the first elastic buffer 1221 is connected to the first connection portion 121, a bottom end of the first elastic buffer 1221 is connected to the first nozzle 1222, and the first nozzle 1222 is slidably connected to the first connection portion 121 by a first connection member 1223. When the first nozzle assembly 122 sucks the product, the pressure on the product can be reduced by the buffering of the first elastic buffering part 1221, thereby reducing the damage to the product. In some alternative embodiments, the first elastic buffer 1221 is rubber; this embodiment is preferably provided as a spring. Specifically, the first connecting member 1223 is slidably connected to the first connecting portion 121 through a slide rail.

In order to facilitate the sucking of the product and reduce the pressure on the product, and to avoid damage to the product due to excessive pressure, as shown in fig. 6, the first nozzle assembly 122 in this embodiment further includes a first pressure feedback element 1224 for feeding back the pressure when the first nozzle 1222 sucks the product, and the first nozzle 1222 can suck the product when the pressure reaches a preset value. Specifically, the first pressure feedback element 1224 is a pressure sensor, and the particular type of pressure sensor may be selected by one skilled in the art as desired, without limitation.

Specifically, the second nozzle assembly 123 includes a first driving part 1231 and a second nozzle 1232, the second nozzle 1232 is slidably connected to the first connection part 121, and the first driving part 1231 is connected to the first connection part 121 and can drive the second nozzle 1232 to move up and down along the first connection part 121. In some alternative embodiments, the first driving part 1231 is a cylinder, a cylinder body of the cylinder is connected to the first connection part 121, and a piston rod of the cylinder is connected to the second suction nozzle 1232. Of course, the first driving portion 1231 may have other structures, which can be selected by those skilled in the art according to the needs, and is not limited herein. Specifically, when the first nozzle assembly 122 sucks the main body portion of the product, the first elastic buffer portion 1221 is in a compressed state when sucking the product, and therefore, when the second nozzle assembly 123 sucks the flat cable of the product, the fifth driving portion 124 needs to drive the first nozzle assembly 122 and the second nozzle assembly 123 to ascend for a certain distance, so that the first elastic buffer portion 1221 is in a free state, and then the first driving portion 1231 drives the second nozzle 1232 to descend to suck the flat cable of the product.

As shown in fig. 1, 7, 8 and 9, the testing mechanism 4 further includes a light shield 41, the testing platform 42 and the second pressing component 43 are both disposed in the light shield 41, and the light shield 41 is used for blocking an external light source, so as to reduce interference of the external light source and improve accuracy of the test.

Specifically, the light shield 41 has a light shield door 411, and the light shield door 411 is connected to a sidewall of the light shield 41 in a lifting manner. When testing the product, light-shielding door 411 closes, gets when putting the product, light-shielding door 411 opens. In some alternative embodiments, the light-shielding door 411 is slidably connected to the side wall of the light-shielding cover 41 by a slide rail. Further, a seventh driving portion 412 is connected to the light-shielding door 411, the seventh driving portion 412 drives the light-shielding door 411 to move up and down, and the seventh driving portion 412 of the present embodiment is preferably an air cylinder, and the specific type thereof can be selected by those skilled in the art as needed, and is not limited herein.

Specifically, a static electricity eliminator 44 is further disposed in the light shield 41 to eliminate static electricity in the light shield 41 and prevent the static electricity from damaging the product.

As shown in fig. 10, the second pressing assembly 43 includes a second connecting portion 431, a third driving portion 432, a fourth driving portion 433, and a second pressing member 434, the second connecting portion 431 is disposed at the bottom of the light shield 41. The third driving part 432 is connected to the second connection part 431; the fourth driving portion 433 is connected to an output end of the third driving portion 432, and the third driving portion 432 is capable of driving the fourth driving portion 433 to approach or move away from the test slot 421 along a horizontal direction. The second pressing member 434 is connected to an output end of the fourth driving portion 433, and the fourth driving portion 433 can drive the second pressing member 434 to approach or move away from the test slot 421 in a vertical direction. When the product in the test slot 421 needs to be pressed, the third driving portion 432 drives the fourth driving portion 433 to approach the product in the horizontal direction, and then the fourth driving portion 433 drives the second pressing member 434 to press down. After the product test is completed, the fourth driving portion 433 drives the second pressing member 434 to ascend, and the third driving portion 432 drives the fourth driving portion 433 to move away from the test slot 421 along the horizontal direction, so that interference caused by taking and placing of the product by the second pressing member 434 can be avoided. In some alternative embodiments, the third driving portion 432 is a cylinder; the fourth driving part 433 is a linear module or a servo module.

Specifically, the second pressing assembly 43 further includes a second elastic buffer portion 435, a top end of the second elastic buffer portion 435 is connected to the fourth driving portion 433, a bottom end of the second elastic buffer portion 435 is connected to the second pressing member 434, and the second pressing member 434 is slidably connected to an output end of the fourth driving portion 433 through a second connecting member 436. When the second pressing member 43 presses the product, the pressure applied to the product is reduced by the buffering of the second elastic buffer portion 435, thereby reducing the damage to the product. In some alternative embodiments, second resilient cushioning portion 435 is rubber; this embodiment is preferably provided as a spring. Specifically, the second connecting member 436 is slidably connected to the output end of the fourth driving portion 433 through a slide rail.

In order to reduce the pressure of the second pressing assembly 43 on the product during the test and avoid damage to the product due to excessive pressure, as shown in fig. 10, the second pressing assembly 43 in this embodiment further includes a second pressure feedback element 437, configured to feed back the pressure when the second pressing member 434 presses the product, and when the pressure reaches a preset value, the second pressing member 434 stops pressing down. Specifically, the second pressure feedback element 437 is a pressure sensor, and the specific type of pressure sensor can be selected by one skilled in the art as needed, and is not limited herein.

As shown in fig. 7, the positioning structure 3 includes a positioning platform 31, a first pressing component 32 and a guiding component 33, the positioning platform 31 has a positioning groove 311 for positioning the product, the shape of the positioning groove 311 matches the shape of the product, specifically, the shape of the positioning groove 311 matches the shape of the product, and when the product is completely located in the positioning groove 311, the product positioning is completed. The first pressing component 32 is connected to the positioning platform 31, the first pressing component 32 is used for pressing the flat cable of the product in the positioning groove 311, the flat cable of the product is soft, and after the flat cable is positioned, the flat cable is pressed through the first pressing component 32, and then the main body of the product is positioned, so that when the main body is positioned, the flat cable is prevented from shaking to cause inaccurate positioning. The guiding component 33 is connected to the positioning platform 31, after the flat cable is pressed by the first pressing component 32, the guiding component 33 guides the main body of the product in the positioning groove 311, and the guiding component 33 makes the main body of the product completely located in the positioning groove 311, thereby completing the positioning of the product.

In order to simplify the structure of the first pressing assembly 32, the first pressing assembly 32 includes a second driving part 321 and a first pressing piece 322, and the second driving part 321 is connected to the positioning platform 31. The first pressing piece 322 is connected to the output end of the second driving part 321, the second driving part 321 can drive the first pressing piece 322 to rotate so that the first pressing piece 322 presses or releases the flat cable in the positioning slot 311, the product is pressed or released through the rotation of the first pressing piece 322, and the interference of the first pressing assembly 32 on the manipulator 1 when the manipulator 1 takes and places the product from the positioning structure 3 is avoided. In some alternative embodiments, the second driving part 321 is a motor, and one end of the first pressing piece 322 is connected to an output end of the motor; in the present embodiment, the second driving unit 321 is preferably a swing cylinder. In some embodiments, the first pressing piece 322 is L-shaped, and one end of the first pressing piece 322 is connected to the execution end of the second driving part 321; the first pressing member 322 is Z-shaped, and one side of the first pressing member 322 is connected to an actuating end of the second driving part 321. Of course, the first pressing member 322 may have other shapes, and the shape is not limited to this, and the flat cable may be pressed or released by the second driving unit 321 without interfering with the product taking and placing of the robot 1.

In order to realize the fast guiding of the main body of the product, as shown in fig. 7, the guiding assembly 33 includes two sixth driving portions 331 and two guiding blocks 332, the two sixth driving portions 331 are respectively connected to the positioning platform 31, each guiding block 332 is respectively connected to an output end of one sixth driving portion 331, the two guiding blocks 332 are respectively located at two opposite corners of the main body portion of the product positioned by the positioning slot 311, a side surface of the guiding block 332 facing the positioning slot 311 is V-shaped, the two sixth driving portions 331 can drive the two guiding blocks 332 to move towards or away from each other, when the two guiding blocks 332 move towards each other, the guiding of the product can be performed, and the product is driven to move into the positioning slot 311. In some alternative embodiments, the sixth driving part 331 is a cylinder.

In order to facilitate conveying the product to the next process, as shown in fig. 1 and 13, the detection structure in this embodiment further includes a blanking platform 5, and the manipulator 1 can convey the tested product to the blanking platform 5.

In order to facilitate separation of good products and defective products after detection, as shown in fig. 1 and 13, the blanking platform 5 includes a good product blanking platform 51 and a defective product blanking platform 52. The manipulator 1 can convey the tested good products to a good product blanking platform 51; the manipulator 1 can convey the defective product after the test to the defective product discharging platform 52. Specifically, the good product blanking platform 51 and the defective product blanking platform 52 are respectively connected to the mounting platform 8, and in some alternative embodiments, the structure of the good product blanking platform 51 is the same as that of the material storage platform 2, and detailed description thereof is omitted; the defective blanking platform 52 includes a defective product receiving platform 521 and a removing assembly 522, the removing assembly 522 is used for conveying the defective product receiving platform 521 to the next process, and the removing assembly 522 includes an eighth driving portion 5221 and a ninth driving portion 5222. The eighth driving unit 5221 is connected to the mounting platform 8 through a third connection 5223, the ninth driving unit 5222 is connected to an output end of the eighth driving unit 5221, the eighth driving unit 5221 can drive the ninth driving unit 5222 to move in the horizontal direction, the defective product bearing table 521 is connected to an output end of the ninth driving unit 5222, and the ninth driving unit 5222 can drive the defective product bearing table 521 to move up and down. When a defective product is detected, the eighth driving unit 5221 drives the ninth driving unit 5222 to move in the horizontal direction, the ninth driving unit 5222 and the defective product bearing table 521 are conveyed to a predetermined material receiving position, the ninth driving unit 5222 drives the defective product bearing table 521 to move up, the manipulator 1 places the defective product in the defective product bearing table 521, the ninth driving unit 5222 drives the defective product bearing table 521 to move down, and the eighth driving unit 5221 drives the ninth driving unit 5222 to move in the horizontal direction, so that the defective product bearing table 521 is conveyed to the next process. Specifically, the specific structure of the defective product receiving platform 521 is the same as that of the storage platform 2, and will not be described in detail here. The third connection member 5223 includes a third connection plate 52231 and a fourth connection plate 52232 connected to the third connection plate 52231, the third connection plate 52231 is connected to the mounting platform 8 and extends in the vertical direction, the fourth connection plate 52232 extends in the horizontal direction, and the eighth driving part 5221 is connected to the fourth connection plate 52232. Specifically, in some alternative embodiments, the eighth driving part 5221 is a rodless cylinder, the ninth driving part 5222 is connected to an execution end of the rodless cylinder through a fifth connection plate 5224, and in order to enable the defective material supporting table 521 to move smoothly, the fifth connection plate 5224 is slidably connected to the fourth connection plate 52232 through a slide rail. In some optional embodiments, the ninth driving portion 5222 is an air cylinder, at least one side of the ninth driving portion 5222 is provided with a sliding block, the sliding block is connected to the fifth connecting plate 5224, the sliding block is slidably connected to a guide rail, and the top end of the guide rail is connected to the defective product supporting platform 521, so that the defective product supporting platform 521 can be lifted and lowered smoothly.

As shown in fig. 4, the detection structure in the present embodiment further includes a first CCD camera 6 and a second CCD camera 7. The first CCD camera 6 is connected to the output end of the mechanical arm 11, so that the manipulator 1 can be accurately positioned when taking and placing materials. The second CCD camera 7 is capable of taking a picture of the product as the manipulator 1 transports the product to the testing mechanism 4. Specifically, second CCD camera 7 is located between location structure 3 and accredited testing organization 4, when manipulator 1 carried the product to accredited testing organization 4 from location structure 3, second CCD camera 7 can shoot the location to the product that manipulator 1 carried, manipulator 1 drives the product and removes to accredited testing organization 4 back, can shoot the location to the position of placing the product in accredited testing organization 4 through first CCD camera 6, after the position of placing the product in the position of the product that manipulator 1 carried and accredited testing organization 4 contrast, thereby can be with the accurate product test position of placing in accredited testing organization 4 of product.

The working principle of the invention is as follows: the manipulator 1 drives the first CCD camera 6 to shoot and locate the products in the material storage platform 2, the materials are taken, after the materials are taken, the manipulator 1 drives the first CCD camera 6 to shoot and locate the positioning groove 311, then the products are placed in the positioning groove 311, the manipulator 1 conveys the products located by the positioning structure 3 to the testing mechanism 4, when the products located by the positioning structure 3 are conveyed to the testing mechanism 4, the second CCD camera 7 shoots the products, when the manipulator 1 conveys the located products to the testing mechanism 4, the first CCD camera 6 shoots and locates the test groove 421, then the products are placed in the test groove 421, finally, the manipulator 1 conveys the tested good products to the good product blanking platform 51, and conveys the tested bad products to the bad product blanking platform 52.

The technical principle of the present invention is described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive effort, which would fall within the scope of the present invention.

Claims (10)

1. A detection structure, comprising:

the manipulator (1) comprises a manipulator (11) and a material taking mechanism (12), the material taking mechanism (12) comprises a first connecting part (121), a first suction nozzle component (122) and a second suction nozzle component (123), the first connecting part (121) is connected to the output end of the manipulator (11) in a lifting mode, the first suction nozzle component (122) and the second suction nozzle component (123) are respectively connected to the first connecting part (121) in a lifting mode, the first suction nozzle component (122) is used for sucking a main body of a product, and the second suction nozzle component (123) is used for sucking a flat cable of the product; and

the testing mechanism (4) comprises a testing platform (42) and a second pressing assembly (43), the testing platform (42) is provided with a testing groove (421), and a probe module for conducting with the product is arranged in the testing groove (421); the second pressing assembly (43) is capable of pressing the product in the test slot (421), and the manipulator (1) is capable of placing the product in the test slot.

2. The detecting structure according to claim 1, wherein the first nozzle assembly (122) includes a first elastic buffer portion (1221) and a first nozzle (1222), a top end of the first elastic buffer portion (1221) is connected to the first connecting portion (121), a bottom end of the first elastic buffer portion (1221) is connected to the first nozzle (1222), and the first nozzle (1222) is slidably connected to the first connecting portion (121) through a first connecting member (1223).

3. The detecting structure according to claim 1, characterized in that the second suction nozzle assembly (123) comprises a first driving portion (1231) and a second suction nozzle (1232), the second suction nozzle (1232) is slidably connected to the first connecting portion (121), and the first driving portion (1231) is connected to the first connecting portion (121) and can drive the second suction nozzle (1232) to move up and down along the first connecting portion (121).

4. The detection structure according to claim 1, characterized in that said second pressing assembly (43) comprises:

a second connection portion (431);

a third driving unit (432) connected to the second connection unit (431);

a fourth driving part (433) connected to an output end of the third driving part (432), wherein the third driving part (432) can drive the fourth driving part (433) to approach or move away from the test slot (421) along a horizontal direction; and

the second pressing piece (434) is connected to the output end of the fourth driving part (433), and the fourth driving part (433) can drive the second pressing piece (434) to approach or move away from the test slot (421) along the vertical direction.

5. The detection structure of claim 1, further comprising:

a first CCD camera (6) connected to an execution end of the mechanical arm (11); and

a second CCD camera (7) capable of taking a picture of the product as it is transported by the manipulator (1) to the testing mechanism (4).

6. The test structure according to claim 1, wherein said testing mechanism (4) further comprises a light shield (41), said testing platform (42) and said second pressing assembly (43) being disposed within said light shield (41), said light shield (41) being configured to block an external light source.

7. The detecting structure according to claim 6, characterized in that the light shielding cover (41) has a light shielding door (411), and the light shielding door (411) is connected to the side wall of the light shielding cover (41) in a lifting manner.

8. The test structure according to any one of claims 1 to 7, characterized in that it further comprises a blanking platform (5), said manipulator (1) being able to convey said products after testing to said blanking platform (5).

9. The detection structure according to claim 8, characterized in that said blanking platform (5) comprises:

the mechanical arm (1) can convey the tested good products to the good product blanking platform (51); and

and the manipulator (1) can convey the tested defective products to the defective product blanking platform (52).

10. A test device comprising a detection structure according to any one of claims 1 to 9.

Images