CN210350356U - Automatic detection and cutting equipment - Google Patents

Abstract

The utility model discloses an automatic detection and cutting device, which comprises an automatic detection device and a cutting device; the automatic detection device comprises a first machine table, a first layer detection mechanism and a second layer detection mechanism, wherein the first layer detection mechanism comprises a first feeding guide rail, a first driving mechanism, a first detection unit, a second detection unit, a third detection unit and a second driving mechanism; the second layer detection mechanism comprises a second feeding guide rail, a fourth detection unit and a third driving mechanism; the cutting device comprises a second machine table, a first layer cutting mechanism and a second layer cutting mechanism, wherein the second layer cutting mechanism is positioned on one side of the first layer cutting mechanism; borrow this, it has realized the automated inspection and cut of shielding part, has guaranteed the uniformity of testing result, has improved detection precision and production efficiency, has reduced manufacturing cost.

Description

Automatic detection and cutting equipment

Technical Field

The utility model relates to a shield check out test set field technique especially indicates an automated inspection and cutting equipment.

Background

The connector plays the effect of lifting the weight in electronic product, it is responsible for realizing data transfer and signal transmission between the electronic product, it is including the terminal usually, shielding part etc., therefore shielding part, the quality of terminal etc. directly influences the quality of electronic product, need detect shielding part, terminal etc. in actual production, adopt manual observation's mode to detect usually among the prior art, such detection mode appears the testing result uniformity poor easily, it is lower to detect the precision, can't guarantee the yields of product, and production efficiency is lower, make manufacturing cost higher.

Therefore, a new technology needs to be developed to solve the above problems.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses to the disappearance that prior art exists, its main objective provides an automated inspection and cutting equipment, and it has realized the automated inspection and the cutting of shielding part, has guaranteed the uniformity of testing result, has improved detection precision and production efficiency, has reduced manufacturing cost.

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

an automatic detection and cutting device comprises an automatic detection device and a cutting device which are sequentially arranged according to a processing sequence;

the automatic detection device comprises a first machine table, a first layer detection mechanism and a second layer detection mechanism, wherein the first layer detection mechanism is arranged on the first machine table and used for detecting a first product on a material belt, the second layer detection mechanism is used for detecting a second product on the material belt, and the second layer detection mechanism is positioned on one side of the first layer detection mechanism;

the first layer detection mechanism comprises a first feeding guide rail, and a first driving mechanism, a first detection unit, a second detection unit, a third detection unit and a second driving mechanism which are sequentially connected with the first feeding guide rail according to the processing sequence;

the second layer detection mechanism comprises a second feeding guide rail, a fourth detection unit and a third driving mechanism, wherein the fourth detection unit and the third driving mechanism are sequentially connected with the second feeding guide rail according to the processing sequence;

the cutting device comprises a second machine table, a first layer cutting mechanism and a second layer cutting mechanism, wherein the first layer cutting mechanism is arranged on the second machine table and used for cutting the first material belt, the second layer cutting mechanism is used for cutting the second material belt, and the second layer cutting mechanism is positioned on one side of the first layer cutting mechanism;

the first detection mechanism, the second detection mechanism, the first layer cutting mechanism and the second layer cutting mechanism are all electrically connected to the control device.

As a preferable scheme, the first driving mechanism and the second driving mechanism are respectively arranged at the input end and the output end of the first feeding guide rail, each of the first driving mechanism, the second driving mechanism and the third driving mechanism comprises a driving unit and a driving wheel, the driving unit is connected to the driving wheel in a driving manner, and the driving wheel is connected above the corresponding feeding guide rail in a linking manner.

As a preferable scheme, a plurality of driving teeth are arranged on the driving wheel and are uniformly arranged at intervals along the circumferential direction of the driving wheel.

As a preferred scheme, the first detection unit comprises a first mounting frame, and a first CCD detector and a first light source which are mounted on the first mounting frame; the first CCD detector is positioned above the first feeding guide rail, and the first light source is positioned between the first CCD detector and the first feeding guide rail.

As a preferable scheme, the second detection unit comprises a second mounting frame, a second CCD detector and a second light source, wherein the second CCD detector and the second light source are mounted on the second mounting frame; the second CCD detector is positioned at the rear side of the first feeding guide rail, and the second light source is arranged above the first feeding guide rail;

the second light source is arranged on the first machine table through the first supporting frame; the first support frame comprises a first cross beam, the first cross beam is transversely arranged above the first feeding guide rail, and the second light source is arranged on the first cross beam.

As a preferable scheme, the third detection unit includes a third mounting frame, a third CCD detector and a third light source, the third CCD detector is mounted on the third mounting frame, the third CCD detector is located at the rear side of the first feeding rail, and the third light source is located at the front side of the first feeding rail.

As a preferable scheme, the fourth detection unit includes a fourth mounting frame, a fourth CCD detector mounted on the fourth mounting frame, and a fourth light source, the fourth CCD detector is located above the second feeding rail, and the fourth light source is located at one side of the fourth CCD detector;

the fourth light source is installed on one side of the second feeding guide rail through a second support frame, the second support frame comprises a second cross beam, the second cross beam is transversely arranged above the second feeding guide rail, and the fourth light source is installed on the second cross beam.

As a preferred scheme, the second layer detection mechanism is installed above the first layer detection mechanism through a first support column, and the second layer detection mechanism comprises a first support plate; one end of the first supporting column is arranged on the first machine table, and the other end of the first supporting column is connected to the first supporting plate;

the second layer cutting mechanism is arranged above the first layer cutting mechanism through a second supporting column and comprises a second supporting plate; one end of the second supporting column is installed on the second machine table, and the other end of the second supporting column is connected to the second supporting plate.

As a preferred scheme, the first layer cutting mechanism and the second layer cutting mechanism respectively comprise a connecting track, a cutting unit, a material pulling mechanism and a blowing device; the input end of the connecting track is connected with the corresponding feeding guide rail, and the cutting unit, the material pulling mechanism and the air blowing device are sequentially arranged according to the processing sequence.

As a preferable scheme, an adjusting mechanism for adjusting the size of the product is arranged at the input end of the first feeding guide rail, the adjusting mechanism is positioned at the input side of the first driving mechanism, and the adjusting mechanism comprises an adjusting rod and an adjusting driving unit for driving the adjusting rod.

Compared with the prior art, the utility model has obvious advantages and beneficial effects, concretely speaking, according to the technical scheme, the automatic detection and cutting of the shielding part are realized mainly by the design that the first detection unit, the second detection unit, the third detection unit and the fourth detection unit are combined with the first layer cutting mechanism and the second layer cutting mechanism, the consistency of the detection result is ensured, the detection precision and the production efficiency are improved, and the production cost is reduced;

and the first layer detection mechanism and the second layer detection mechanism which are arranged in an up-down stacked mode are combined with the first layer cutting mechanism and the second layer cutting mechanism which are arranged in an up-down stacked mode, so that the up-down stacked design is realized, the overall structural layout is more reasonable, the overall occupied area is reduced, and the occupied space is reduced.

To more clearly illustrate the structural features and technical means of the present invention and the specific objects and functions achieved thereby, the present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 2 is a schematic view of the embodiment of the present invention with the protective door removed;

FIG. 3 is a schematic view of a partial structure of an embodiment of the present invention;

fig. 4 is another partial structural schematic diagram of the embodiment of the present invention.

The attached drawings indicate the following:

10. first machine 20 and first layer detection mechanism

21. First feeding guide rail 22 and first driving mechanism

23. First detection unit 231 and first mounting rack

232. First CCD Detector 233, first light Source

24. Second detection unit 241 and second mounting rack

242. Second CCD Detector 243, second light Source

244. First support frame 245 and first cross beam

25. Third detection unit 251 and third mounting rack

252. Third CCD Detector 253 and third light Source

26. Second driving mechanism 30 and second layer detection mechanism

31. Second feeding guide rail 32 and fourth detection unit

321. Fourth mounting bracket 322, fourth CCD detector

33. Third driving mechanism 40 and second machine

50. First layer cutting mechanism 60 and second layer cutting mechanism

70. Adjusting mechanism 71 and adjusting rod

72. Adjustment drive unit 101, drive unit

102. Drive wheel 103, first support column

104. First support plate 105, second support column

106. Second supporting plate 201, joining rail

202. Cutting unit 2021, positioning seat

2022. Cutting drive unit 2023, cutting block

203. Pulling mechanism 2031 and base

2032. Pulling driving unit 2033 and pulling wheel

204. Air blowing device 301 and protective door

302. Leading-in groove 303 and leading-out groove

401. Material receiving frame 402 and paper bag emptying disc

403. And (7) receiving a material tray.

Detailed Description

Please refer to fig. 1 to 4, which show the specific structure of the embodiment of the present invention; the method is mainly applied to the detection and cutting of the shielding part product, certainly, the method is not limited to the detection and cutting of the shielding part product, and other products can be detected and cut, and the following description will be given by applying the method to the detection and cutting of the shielding part.

The automatic detection and cutting equipment comprises an automatic detection device and a cutting device which are sequentially arranged according to the processing sequence;

the automatic detection device comprises a first machine table 10, a first layer detection mechanism 20 and a second layer detection mechanism 30, wherein the first layer detection mechanism 20 is arranged on the first machine table 10 and used for detecting a first product on a material belt, the second layer detection mechanism 30 is used for detecting a second product on the material belt, and the second layer detection mechanism 30 is positioned on one side of the first layer detection mechanism 20; the first layer detection mechanism 20 comprises a first feeding guide rail 21, and a first driving mechanism 22, a first detection unit 23, a second detection unit 24, a third detection unit 25 and a second driving mechanism 26 which are sequentially connected with the first feeding guide rail 21 according to the process sequence; the second layer detection mechanism 30 comprises a second feeding guide rail 31, a fourth detection unit 32 and a third driving mechanism 33 which are sequentially connected with the second feeding guide rail 31 according to the process sequence; the cutting device comprises a second machine table 40, a first layer cutting mechanism 50 and a second layer cutting mechanism 60, wherein the first layer cutting mechanism 50 and the second layer cutting mechanism 60 are arranged on the second machine table 40 and used for cutting a first material belt, and the second layer cutting mechanism 60 is positioned on one side of the first layer cutting mechanism 50; the first detection mechanism, the second detection mechanism, the first layer cutting mechanism 50 and the second layer cutting mechanism 60 are all electrically connected to the control device. Here, the first machine 10 and the second machine 40 may be combined into one machine or may be composed of two machines according to actual requirements, which is not described herein.

The first driving mechanism 22 and the second driving mechanism 26 are respectively arranged at the input end and the output end of the first feeding guide rail 21, the first driving mechanism 22, the second driving mechanism 26 and the third driving mechanism 33 respectively comprise a driving unit 101 and a driving wheel 102, the driving unit 101 is connected to the driving wheel 102 in a driving manner, and the driving wheel 102 is connected above the corresponding feeding guide rail; the driving wheel 102 is provided with a plurality of driving teeth which are uniformly arranged along the circumferential direction of the driving wheel 102 at intervals; here, the driving unit 101 is preferably motor-driven, but of course, is not limited to motor-driven; therefore, through the arrangement of the driving teeth, the driving wheel 102 can be adapted to the through hole on the material belt through the driving teeth, so that the material belt is more stably driven and conveyed, and the phenomenon that the material belt is influenced by the driving slip is avoided.

The first detection unit 23 comprises a first mounting frame 231, a first CCD detector 232 and a first light source 233, which are mounted on the first mounting frame 231; the first CCD detector 232 is positioned above the first feeding guide rail 21, and the first light source 233 is positioned between the first CCD detector 232 and the first feeding guide rail 21; here, the first CCD detector 232 is used to detect the fisheye contour and the position dimension of the product.

The second detection unit 24 includes a second mounting frame 241, a second CCD detector 242 mounted on the second mounting frame 241, and a second light source 243; the second CCD detector 242 is located at the rear side of the first feeding rail 21, and the second light source 243 is disposed above the first feeding rail 21; the second light source 243 is mounted on the first machine 10 through the first supporting frame 244; the first support frame 244 comprises a first beam 245, the first beam 245 is transversely arranged above the first feeding rail 21, and the second light source 243 is installed on the first beam 245.

The third detecting unit 25 includes a third mounting bracket 251, a third CCD detector 252 and a third light source 253, the third CCD detector 252 is mounted on the third mounting bracket 251, the third CCD detector 252 is located at the rear side of the first feeding rail 21, and the third light source 253 is located at the front side of the first feeding rail 21. Here, the second and third CCD detectors 242 and 252 are used to detect the elastic height and the angular size of the terminals of the product.

The fourth detection unit 32 comprises a fourth mounting rack 321, a fourth CCD detector 322 mounted on the fourth mounting rack 321, and a fourth light source, the fourth CCD detector 322 is located above the second feeding rail 31, and the fourth light source is located at one side of the fourth CCD detector 322; the fourth light source is installed on one side of the second feeding guide rail 31 through a second support frame, the second support frame comprises a second cross beam, the second cross beam is transversely arranged above the second feeding guide rail 31, and the fourth light source is installed on the second cross beam.

The second layer detection mechanism 30 is mounted above the first layer detection mechanism 20 through a first support column 103, and the second layer detection mechanism 30 comprises a first support plate 104; one end of the first support column 103 is mounted on the first machine table 10, and the other end is connected to the first support plate 104; the second layer cutting mechanism 60 is mounted above the first layer cutting mechanism 50 by a second support column 105, the second layer cutting mechanism 60 includes a second support plate 106; one end of the second supporting column 105 is installed on the second machine platform 40, and the other end is connected to the second supporting plate 106. Therefore, the overall structure layout of the multi-layer cutting machine is more reasonable by combining the first layer detection mechanism 20 and the second layer detection mechanism 30 which are arranged in an up-down stacking manner and the first layer cutting mechanism 50 and the second layer cutting mechanism 60 which are arranged in an up-down stacking manner, and the overall occupied area is reduced so as to reduce the occupation of space.

The first layer cutting mechanism 50 and the second layer cutting mechanism 60 respectively comprise a connecting track 201, a cutting unit 202, a material pulling mechanism 203 and a blowing device 204; the input end of the connecting track 201 is connected to the corresponding feeding guide rail, and the cutting unit 202, the material pulling mechanism 203 and the air blowing device 204 are sequentially arranged according to the process sequence.

The cutting unit 202 comprises a positioning seat, a cutting driving unit 2022 and a cutting block 2023, wherein the cutting driving unit 2022 and the cutting block 2023 are arranged on the positioning seat, and the cutting driving unit 2022 is connected with the cutting block 2023 in a driving manner; the cutting drive unit 2022 is preferably, but not limited to, cylinder driven; the material pulling mechanism 203 comprises a base 2031, a material pulling driving unit 2032 and a material pulling wheel 2033, wherein the material pulling driving unit 2032 and the material pulling wheel 2033 are arranged on the base 2031, the material pulling driving unit 2032 is in driving connection with the material pulling wheel 2033, a plurality of material pulling teeth are arranged on the material pulling wheel 2033, and the plurality of material pulling teeth are uniformly arranged along the circumferential direction of the material pulling wheel 2033 at intervals; the material pulling driving unit 2032 is preferably motor-driven, but is not limited to motor-driven.

The air blowing device 204 comprises an air blowing mechanism, an air suction mechanism and a driving unit; the driving unit drives the blowing mechanism and the air suction mechanism to blow away and suck metal scraps generated by cutting, so that the cleanness of a product is ensured; here, the driving unit is preferably driven by a cylinder, but is not limited to the cylinder driving.

In addition, in this embodiment, an adjusting mechanism 70 for adjusting the size of the product is disposed at the input end of the first feeding rail 21, the adjusting mechanism 70 is located at the input side of the first driving mechanism 22, the adjusting mechanism 70 includes an adjusting rod 71 and an adjusting driving unit 72 for driving the adjusting rod 71, and the adjusting driving unit 72 drives the adjusting rod 71 to reciprocate on the first feeding rail 21, so that the adjusting rod 71 adjusts the spring height of the elastic arm of the shielding member; the adjustment driving unit 72 is preferably driven by an air cylinder, but is not limited to the air cylinder; the adjusting lever 71 has an adjusting tab for adjusting the spring height of the spring arm of the plug-in shield.

The first machine table 10 and the second machine table 40 are further provided with a protective door 301, and the automatic detection device and the cutting device are protected by the protective door 301; and the input ends corresponding to the first feeding guide rail 21 and the second feeding guide rail 31 are provided with leading-in grooves 302, the output ends of the joining rails 201 are provided with leading-out grooves 303, the output side of the second machine table 40 is also provided with a material receiving frame 401, and the material receiving frame 401 is provided with a paper bag discharging disc 402 and a material receiving disc 403.

In summary, the design of the utility model is mainly characterized in that the first detection unit, the second detection unit, the third detection unit and the fourth detection unit are combined with the first layer cutting mechanism and the second layer cutting mechanism, so that the automatic detection and cutting of the shielding part are realized, the consistency of the detection result is ensured, the detection precision and the production efficiency are improved, and the production cost is reduced; and the first layer detection mechanism and the second layer detection mechanism which are arranged in an up-down stacked mode are combined with the first layer cutting mechanism and the second layer cutting mechanism which are arranged in an up-down stacked mode, so that the up-down stacked design is realized, the overall structural layout is more reasonable, the overall occupied area is reduced, and the occupied space is reduced.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (10)

1. The utility model provides an automated inspection and cutting equipment which characterized in that: comprises an automatic detection device and a cutting device which are arranged in sequence according to the process sequence;

the automatic detection device comprises a first machine table, a first layer detection mechanism and a second layer detection mechanism, wherein the first layer detection mechanism is arranged on the first machine table and used for detecting a first product on a material belt, the second layer detection mechanism is used for detecting a second product on the material belt, and the second layer detection mechanism is positioned on one side of the first layer detection mechanism;

the first layer detection mechanism comprises a first feeding guide rail, and a first driving mechanism, a first detection unit, a second detection unit, a third detection unit and a second driving mechanism which are sequentially connected with the first feeding guide rail according to the processing sequence;

the second layer detection mechanism comprises a second feeding guide rail, a fourth detection unit and a third driving mechanism, wherein the fourth detection unit and the third driving mechanism are sequentially connected with the second feeding guide rail according to the processing sequence;

the cutting device comprises a second machine table, a first layer cutting mechanism and a second layer cutting mechanism, wherein the first layer cutting mechanism is arranged on the second machine table and used for cutting the first material belt, the second layer cutting mechanism is used for cutting the second material belt, and the second layer cutting mechanism is positioned on one side of the first layer cutting mechanism;

the first detection mechanism, the second detection mechanism, the first layer cutting mechanism and the second layer cutting mechanism are all electrically connected to the control device.

2. The automatic detection and cutting apparatus of claim 1, wherein: the first driving mechanism and the second driving mechanism are respectively arranged at the input end and the output end of the first feeding guide rail, the first driving mechanism, the second driving mechanism and the third driving mechanism respectively comprise a driving unit and a driving wheel, the driving unit is connected to the driving wheel in a driving mode, and the driving wheel is connected above the corresponding feeding guide rail in a connecting mode.

3. The automatic detection and cutting apparatus of claim 2, wherein: the driving wheel is provided with a plurality of driving teeth which are uniformly arranged along the circumferential direction of the driving wheel at intervals.

4. The automatic detection and cutting apparatus of claim 1, wherein: the first detection unit comprises a first mounting rack, a first CCD detector and a first light source, wherein the first CCD detector and the first light source are mounted on the first mounting rack; the first CCD detector is positioned above the first feeding guide rail, and the first light source is positioned between the first CCD detector and the first feeding guide rail.

5. The automatic detection and cutting apparatus of claim 1, wherein: the second detection unit comprises a second mounting rack, a second CCD detector and a second light source, wherein the second CCD detector and the second light source are mounted on the second mounting rack; the second CCD detector is positioned at the rear side of the first feeding guide rail, and the second light source is arranged above the first feeding guide rail;

the second light source is arranged on the first machine table through the first supporting frame; the first support frame comprises a first cross beam, the first cross beam is transversely arranged above the first feeding guide rail, and the second light source is arranged on the first cross beam.

6. The automatic detection and cutting apparatus of claim 1, wherein: the third detection unit comprises a third mounting frame, a third CCD detector and a third light source, the third CCD detector is installed on the third mounting frame, the third CCD detector is located on the rear side of the first feeding guide rail, and the third light source is located on the front side of the first feeding guide rail.

7. The automatic detection and cutting apparatus of claim 1, wherein: the fourth detection unit comprises a fourth mounting rack, a fourth CCD detector and a fourth light source, the fourth CCD detector is mounted on the fourth mounting rack, the fourth CCD detector is positioned above the second feeding guide rail, and the fourth light source is positioned on one side of the fourth CCD detector;

the fourth light source is installed on one side of the second feeding guide rail through a second support frame, the second support frame comprises a second cross beam, the second cross beam is transversely arranged above the second feeding guide rail, and the fourth light source is installed on the second cross beam.

8. The automatic detection and cutting apparatus of claim 1, wherein: the second-layer detection mechanism is arranged above the first-layer detection mechanism through a first supporting column and comprises a first supporting plate; one end of the first supporting column is arranged on the first machine table, and the other end of the first supporting column is connected to the first supporting plate;

the second layer cutting mechanism is arranged above the first layer cutting mechanism through a second supporting column and comprises a second supporting plate; one end of the second supporting column is installed on the second machine table, and the other end of the second supporting column is connected to the second supporting plate.

9. The automatic detection and cutting apparatus of claim 1, wherein: the first layer cutting mechanism and the second layer cutting mechanism respectively comprise a connecting track, a cutting unit, a material pulling mechanism and a blowing device; the input end of the connecting track is connected with the corresponding feeding guide rail, and the cutting unit, the material pulling mechanism and the air blowing device are sequentially arranged according to the processing sequence.

10. The automatic detection and cutting apparatus of claim 1, wherein: the input end of the first feeding guide rail is provided with an adjusting mechanism for adjusting the size of a product, the adjusting mechanism is located on the input side of the first driving mechanism, and the adjusting mechanism comprises an adjusting rod and an adjusting driving unit for driving the adjusting rod.

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