CN214426629U - 3D detection device for high-smooth-surface complex-structure nanocrystalline - Google Patents

Abstract

The utility model relates to a testing arrangement technical field relates to a high smooth surface complex construction nanocrystalline's 3D detection device. The utility model discloses a product carrier carries out the quick location to the coil product, and the detection part carries out the thickness detection to the coil product fast, has effectively improved production efficiency, has reduced workman's intensity of labour, has also satisfied a large amount of detection demands in the production simultaneously; the coil on the lift drive part drives the product carrier simultaneously and detects benchmark subassembly butt, can effectively improve through the reference surface measurement and detect the precision, is particularly suitable for carrying out thickness test to products such as coil panel of overall flatness, provides the powerful guarantee for product quality's improvement.

Description

3D detection device for high-smooth-surface complex-structure nanocrystalline

Technical Field

The utility model relates to a testing arrangement technical field relates to a high smooth surface complex construction nanocrystalline's 3D detection device.

Background

The existing small electronic consumer products such as mobile phones and the like gradually start to use wireless charging to thoroughly put an end to the traditional wired connection mode. In the production process of a wireless charging coil (with a magnet nanocrystalline coil), the thickness of a coil panel is required to be tested frequently, a height gauge or an over-gauge instrument is generally adopted to check the thickness of the coil at present, the testing method is low in efficiency, time and labor are wasted, after multi-point measurement is carried out, multiple groups of data are analyzed and compared, the accuracy is difficult to guarantee, and the method is not suitable for a factory mass production mode.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide an improve production efficiency, reduced workman's intensity of labour, effectively improve and detect the precision, provide the brilliant 3D detection device of high smooth surface complex construction nanometer for product quality's improvement.

In order to solve the technical problem, the utility model provides a technical scheme that its technical problem adopted is:

A3D detection device for a high-gloss-surface complex-structure nanocrystalline comprises a reference frame and a lifting frame, wherein the lifting frame is connected with the reference frame, a detection reference assembly is arranged on the reference frame, a lifting frame and a lifting driving part are arranged on the lifting frame in a sliding mode, a product carrier used for containing a product to be detected is arranged on the lifting frame, the lifting driving part is in driving connection with the lifting frame, the lifting driving part drives the lifting frame to do reciprocating linear motion, and the detection reference assembly and the product carrier are arranged oppositely;

and the detection part is arranged on the jacking frame and is arranged below the product carrier.

Furthermore, the detection reference assembly comprises a reference plate, a reference groove is formed in the reference plate, and optical glass is fixedly connected to the reference groove.

Further, the product carrier comprises a carrier plate, a positioning component for positioning a product to be detected is arranged on the carrier plate, and the product is adsorbed on the carrier plate by the positioning component.

Furthermore, the positioning component comprises a vacuum sealing plate, the vacuum sealing plate is arranged at the bottom of the carrier plate, and a plurality of adsorption holes communicated with the vacuum sealing plate are formed in the carrier plate.

Further, the detection part comprises a plurality of linear displacement sensors, a detection frame is arranged on the lifting plate, the linear displacement sensors are arranged on the detection frame, detection through holes are formed in the carrier plate, and ceramic detection heads on the linear displacement sensors penetrate through the detection through holes.

Further, be provided with the tablet on the product carrier, be provided with on the benchmark frame with tablet assorted proximity sensor, the tablet with proximity sensor sets up relatively.

Further, a cylinder frame is arranged on the reference frame, a carrier pressing cylinder is arranged on the cylinder frame, and the carrier pressing cylinder is in driving connection with the detection reference assembly.

Further, lift drive part includes jacking cylinder down, be provided with the lift slide rail on the crane, the jacking erects to slide and establishes on the lift slide rail, lower jacking cylinder with the crane is connected, lower jacking cylinder piston rod end with jacking frame drive connection, lower jacking cylinder drives jacking frame is reciprocal linear motion along the lift slide rail.

Further, the crane with be provided with adjusting part between the benchmark frame, adjusting part includes the front and back regulating unit and controls the regulating unit, the front and back regulating unit is the same with controlling the regulating unit structure, the front and back regulating unit sets up control on the regulating unit, control the regulating unit with the benchmark frame is connected, the front and back regulating unit with the crane is connected, finely tunes the relative position of crane and benchmark frame through adjusting part.

Furthermore, the left-right adjusting unit comprises a first plate and a second plate, the first plate is slidably arranged on the second plate, an adjusting frame is arranged on the second plate, a micrometer is arranged on the adjusting frame, and a distance measuring end of the micrometer is connected with the first plate.

The utility model has the advantages that:

the utility model discloses a product carrier carries out the quick location to the coil product, and the detection part carries out the thickness detection to the coil product fast, has effectively improved production efficiency, has reduced workman's intensity of labour, has also satisfied a large amount of detection demands in the production simultaneously; the coil on the lift drive part drives the product carrier simultaneously and detects benchmark subassembly butt, can effectively improve through the reference surface measurement and detect the precision, is particularly suitable for carrying out thickness test to products such as coil panel of overall flatness, provides the powerful guarantee for product quality's improvement.

Drawings

Fig. 1 is a schematic view of the 3D detection device for the nanocrystals with the complex structure and the high optical surface of the present invention.

Fig. 2 is a schematic view of the detection reference assembly of the present invention.

Fig. 3 is a schematic view of the product carrier of the present invention.

Fig. 4 is a schematic view of an adjustment member of the present invention.

The reference numbers in the figures illustrate: 1. a reference frame; 2. a reference plate; 21. an optical glass; 22. the carrier presses the air cylinder downwards; 23. a cylinder frame; 3. a product carrier; 31. an induction plate; 32. a proximity sensor; 33. an adsorption hole; 34. a vacuum suction plate; 35. detecting the through hole; 4. a lifting frame; 41. a jacking frame; 42. a lower jacking cylinder; 43. lifting the slide rail; 44. a detection frame; 45. a linear displacement sensor; 46. a ceramic detection head; 5. an adjustment member; 51. a front-rear adjusting unit; 52. a left-right adjusting unit; 53. a first plate; 54. a second plate; 55. a micrometer;

Detailed Description

The present invention is further described with reference to the following drawings and specific embodiments so that those skilled in the art can better understand the present invention and can implement the present invention, but the embodiments are not to be construed as limiting the present invention.

Referring to fig. 1-4, a 3D detection device for a high-gloss-surface complex-structure nanocrystalline comprises a reference frame 1 and a lifting frame 4, wherein the lifting frame 4 is connected with the reference frame 1, a detection reference assembly is arranged on the reference frame 1, a lifting frame 41 and a lifting driving part are arranged on the lifting frame 4 in a sliding manner, a product carrier 3 for accommodating a product to be detected is arranged on the lifting frame 41, the lifting driving part is in driving connection with the lifting frame 41, the lifting driving part drives the lifting frame 41 to make reciprocating linear motion, and the detection reference assembly is arranged opposite to the product carrier 3;

the jacking frame 41 is provided with a detection part, and the detection part is arranged below the product carrier 3.

The utility model has the advantages that the product carrier 3 can quickly position the coil product, the detection part can quickly detect the thickness of the coil product, the production efficiency is effectively improved, the labor intensity of workers is reduced, and a large amount of detection requirements in production are met; and meanwhile, the lifting driving part drives the coil on the product carrier 3 to abut against the detection reference assembly, the detection precision can be effectively improved through reference surface measurement, the thickness test device is particularly suitable for thickness test of products with overall flatness such as coil panels and the like, and powerful guarantee is provided for improvement of product quality.

The detection reference assembly comprises a reference plate 2, a reference groove is formed in the reference plate 2, and optical glass 21 is fixedly connected to the reference groove.

The flatness of the optical glass 21 can reach 0.003mm, which is beneficial to improving the detection accuracy; the optical glass 21 and the reference plate 2 are fixedly arranged, so that the constant detection reference position can be ensured, and good repeatability is achieved.

The product carrier 3 comprises a carrier plate, a positioning component for positioning a product to be detected is arranged on the carrier plate, and the product is adsorbed on the carrier plate by the positioning component.

The positioning component comprises a vacuum sealing plate, the vacuum sealing plate is arranged at the bottom of the carrier plate, and a plurality of adsorption holes 33 communicated with the vacuum sealing plate are formed in the carrier plate.

The detection part comprises a plurality of linear displacement sensors 45, a detection frame 44 is arranged on the lifting plate, the linear displacement sensors 45 are arranged on the detection frame 44, a detection through hole 35 is formed in the carrier plate, and a ceramic detection head 46 on the linear displacement sensors 45 is arranged on the detection through hole 35 in a penetrating mode.

The linear displacement sensor 45 adopts an LVDT linear displacement sensor 45, the detection precision can reach 0.1 mu m, and meanwhile, a ceramic detection head 46 in contact with a product can be used for detecting the product with the magnet, so that the product cannot be damaged and magnetized, and the detection precision is ensured.

Be provided with tablet 31 on the product carrier 3, be provided with on the benchmark frame 1 with tablet 31 assorted proximity sensor 32, tablet 31 with proximity sensor 32 sets up relatively.

After the induction plate 31 is contacted with the proximity sensor 32, the position precision of the coil product is ensured, and the detection precision of the detection component is improved.

The reference frame 1 is provided with a cylinder frame 23, the cylinder frame 23 is provided with a carrier pressing cylinder 22, and the carrier pressing cylinder 22 is in driving connection with the detection reference assembly.

The carrier is pressed down by the air cylinder 22, so that the carrier can be in complete contact with the reference plate 2, the product carrier 3 is prevented from being separated from the reference plate 2, the stability of the equipment is improved, the product is in complete contact with one surface of the optical glass 21, the LVDT sensor is used for measuring the other surface of the product after being reset to zero on the optical glass 21, and the real thickness of the product is obtained through the displacement difference.

The lift drive part includes jacking cylinder 42 down, be provided with lift slide rail 43 on the crane 4, jacking frame 41 slides and establishes on the lift slide rail 43, jacking cylinder 42 down with crane 4 is connected, jacking cylinder 42 piston rod end down with jacking frame 41 drive connection, jacking cylinder 42 drives down jacking frame 41 is reciprocating linear motion along lift slide rail 43.

The crane 4 with be provided with adjusting part 5 between the benchmark frame 1, adjusting part 5 includes around adjusting unit 51 and control adjusting unit 52, around adjusting unit 51 with control adjusting unit 52 structure the same, around adjusting unit 51 sets up control on the adjusting unit 52, control adjusting unit 52 with benchmark frame 1 is connected, around adjusting unit 51 with crane 4 is connected, finely tunes crane 4 and benchmark frame 1's relative position through adjusting part 5.

The left-right adjusting unit 52 comprises a first plate 53 and a second plate 54, the first plate 53 is slidably arranged on the second plate 54, an adjusting frame is arranged on the second plate 54, a micrometer 55 is arranged on the adjusting frame, and a distance measuring end of the micrometer 55 is connected with the first plate 53.

The front-back adjusting unit 51 and the left-right adjusting unit 52 are finely adjusted by adjusting the micrometer 55, so that the relative position of the product carrier 3 and the optical glass 21 can be adjusted, the flatness during detection is ensured, and the detection precision is improved.

Application process

The coil product to be detected is placed on the product carrier 3 to be adsorbed and positioned, the lower jacking cylinder 42 drives the coil product on the product carrier 3 to abut against the optical glass 21, the carrier lower pressing cylinder 22 drives the reference plate 2 to press downwards, so that the carrier is in complete contact with the reference plate 2, and the ceramic detection head 46 extends out of the abutting joint coil surface to obtain thickness information of each position of the coil product.

The above-mentioned embodiments are merely preferred embodiments for fully illustrating the present invention, and the scope of the present invention is not limited thereto. Equivalent substitutes or changes made by the technical personnel in the technical field on the basis of the utility model are all within the protection scope of the utility model. The protection scope of the present invention is subject to the claims.

Claims (10)

1. A3D detection device for a high-gloss-surface complex-structure nanocrystalline is characterized by comprising a reference frame and a lifting frame, wherein the lifting frame is connected with the reference frame, a detection reference assembly is arranged on the reference frame, a lifting frame and a lifting driving part are arranged on the lifting frame in a sliding manner, a product carrier for accommodating a product to be detected is arranged on the lifting frame, the lifting driving part is in driving connection with the lifting frame, the lifting driving part drives the lifting frame to do reciprocating linear motion, and the detection reference assembly and the product carrier are arranged oppositely;

and the detection part is arranged on the jacking frame and is arranged below the product carrier.

2. The 3D detection device for the nanocrystals with the complex structure and the high optical surface as claimed in claim 1, wherein the detection reference assembly comprises a reference plate, the reference plate is provided with a reference groove, and the reference groove is fixedly connected with an optical glass.

3. The apparatus according to claim 1, wherein the product carrier comprises a carrier plate, and a positioning member is disposed on the carrier plate for positioning a product to be detected, and the positioning member attaches the product to the carrier plate.

4. The apparatus according to claim 3, wherein the positioning member comprises a vacuum sealing plate disposed at a bottom of the carrier plate, and the carrier plate has a plurality of adsorption holes communicating with the vacuum sealing plate.

5. The apparatus according to claim 3, wherein the detecting member comprises a plurality of linear displacement sensors, the lifting frame is provided with a detecting frame, the linear displacement sensors are disposed on the detecting frame, the carrier plate is provided with a detecting through hole, and a ceramic detecting head of the linear displacement sensor is disposed through the detecting through hole.

6. The apparatus according to claim 1, wherein the product carrier has a sensor board, the reference frame has a proximity sensor matching the sensor board, and the sensor board is opposite to the proximity sensor.

7. The apparatus according to claim 1, wherein a cylinder frame is disposed on the reference frame, and a carrier down-pressure cylinder is disposed on the cylinder frame and is in driving connection with the detection reference assembly.

8. The 3D detection apparatus for nanocrystals with high optical surface area and complex structure as claimed in claim 1, wherein the lifting driving component comprises a lower jacking cylinder, the lifting frame is provided with a lifting slide rail, the jacking frame is slidably disposed on the lifting slide rail, the lower jacking cylinder is connected to the lifting frame, the rod end of the piston rod of the lower jacking cylinder is drivingly connected to the jacking frame, and the lower jacking cylinder drives the jacking frame to make a reciprocating linear motion along the lifting slide rail.

9. The 3D detection apparatus for nanocrystals with a complex structure and a high optical surface as claimed in claim 1, wherein an adjustment unit is disposed between the lifting frame and the reference frame, the adjustment unit comprises a front and back adjustment unit and a left and right adjustment unit, the front and back adjustment unit and the left and right adjustment unit have the same structure, the front and back adjustment unit is disposed on the left and right adjustment unit, the left and right adjustment unit is connected to the reference frame, the front and back adjustment unit is connected to the lifting frame, and the relative position between the lifting frame and the reference frame is finely adjusted by the adjustment unit.

10. The 3D detection device for the nanocrystals with the high optical surface and the complex structure as defined in claim 9, wherein the left and right adjustment units comprise a first plate and a second plate, the first plate is slidably disposed on the second plate, the second plate is disposed with an adjustment frame, the adjustment frame is disposed with a micrometer, and a distance measurement end of the micrometer is connected to the first plate.

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