CN220187642U - Thickness detection equipment for glass production - Google Patents

Abstract

The utility model discloses thickness detection equipment for glass production, which comprises the following technical scheme: the device comprises a device table and a detection table, wherein a supporting table is arranged in the middle of the front surface of the device table, the detection table is arranged in the middle of the top of the device table, a conveying belt A is arranged on one side of the top of the device table, glass is arranged in the middle of the top of the conveying belt A, a conveying belt B is arranged on one side, deviating from the conveying belt A, of the top of the device table, an electric telescopic device is arranged in the middle of the bottom of the supporting table, a detection frame is arranged at the top of an output shaft of the electric telescopic device, and a screw rod B is arranged in the middle of the inside of the detection frame. The utility model provides a thickness check out test set that glass production was used has solved current majority thickness check out test set and has needed manual material loading and unloading to glass, intensity of labour is big, and detection efficiency is not good, and the glass goes up the unloading unable synchronous, influences the problem of glass thickness detection efficiency, has improved glass's material loading and unloading efficiency to glass thickness's detection efficiency has been improved.

Description

Thickness detection equipment for glass production

Technical Field

The utility model relates to the technical field of glass production, in particular to thickness detection equipment for glass production.

Background

Glass is an amorphous inorganic nonmetallic material, which is generally prepared from a plurality of inorganic minerals serving as main raw materials and a small amount of auxiliary raw materials, is widely applied to buildings, is used for isolating wind and transmitting light, belongs to a mixture, and is further mixed with colored glass which is prepared by certain metal oxides or salts and shows color, toughened glass prepared by a physical or chemical method, and the like, wherein the thickness of the glass is required to be detected during production.

Through the mass retrieval, it is found that thickness detection equipment among the prior art is as disclosed in publication number CN216645162U thickness detection device for toughened glass production, put toughened glass on placing the board, utilize spring extrusion chucking board to press from both sides tight with toughened glass one side, and support toughened glass's opposite side through the rubber pad, make toughened glass stably fix fast on placing the board, when having solved current thickness detection instrument and carrying out the side thickness to toughened glass, need stably fix toughened glass four corners and measure on measuring plate, fix with dismantlement work loaded down with trivial details, influence measurement efficiency's problem greatly.

Most of the existing thickness detection equipment needs to manually feed and discharge glass, the labor intensity is high, the detection efficiency is poor, and the feeding and discharging of the glass cannot be synchronous, so that the detection efficiency of the thickness of the glass is affected.

Disclosure of Invention

The utility model aims to provide thickness detection equipment for glass production, which has the advantage of synchronous feeding and discharging, and solves the problems that most of the existing thickness detection equipment needs to manually feed and discharge glass, has high labor intensity and poor detection efficiency, and the feeding and discharging of the glass cannot be synchronous, so that the detection efficiency of the thickness of the glass is affected.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a thickness check out test set that glass production used, includes equipment table and detection platform, wherein install the supporting bench in the middle of the equipment table front surface, install the detection platform in the middle of the equipment table top, conveyer belt A is installed to equipment table top one side, be equipped with glass in the middle of the conveyer belt A top, conveyer belt B is installed to equipment table top one side that deviates from conveyer belt A, install electric telescopic in the middle of the supporting bench bottom, the detection frame is installed at electric telescopic output shaft top, install lead screw B in the middle of the detection frame inside, the slider has been cup jointed in the middle of the lead screw B surface, motor B is installed to lead screw B one end, install the support frame in the middle of the slider rear surface, the support frame rear surface both sides are all installed and are snatched the frame, snatch the frame lower surface and install vacuum chuck through the bracing piece.

Preferably, the locating rack is installed near the middle of the rear surface at the top of the equipment table, the testing rack is installed in the middle of the lower surface of the tail end of the locating rack through the connecting rod, the screw rod A is installed in the middle of the inside of the testing rack, and the motor A is installed at one end of the screw rod A, which is located at one side of the testing rack.

Preferably, the middle of the outer surface of the screw rod A is sleeved with a sliding plate, a photoelectric sensor is arranged in the middle of the lower surface of the sliding plate, the top of the sliding plate is in friction contact with the test frame, a display is arranged in the middle of the top of the positioning frame, and the display is electrically connected with the photoelectric sensor.

Preferably, the middle of two sides of the lower surface of the detection frame is provided with a sliding rod, and the two sides of the sliding rod are inserted into the supporting table.

Preferably, the lower surface of the sliding block is in friction contact with the detection frame, and the inclined strut is arranged on the rear surface of the sliding block at the clearance position of the support frame.

Preferably, the grabbing frames are arranged in two in total, the grabbing frames are arranged at two sides of the rear surface of the supporting frame, and detection holes are formed in the middle of the inner parts of the grabbing frames.

Preferably, the vacuum chucks are provided with eight in total, the eight vacuum chucks are equally divided into two groups, and the two groups of vacuum chucks are respectively arranged at four corner positions of the lower surfaces of the grabbing frames at two sides.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the glass feeding and discharging device, the effect of synchronously feeding and discharging glass is achieved by arranging the sliding blocks, the two grabbing frames and the vacuum chuck, the glass after detection is fed through the grabbing frame and the vacuum chuck on one side, and meanwhile, the glass to be detected is fed through the grabbing frame and the vacuum chuck on the other side, so that the problems that most of thickness detection equipment needs to feed and discharge the glass manually, labor intensity is high, detection efficiency is poor, feeding and discharging of the glass cannot be synchronous, and detection efficiency of glass thickness is affected are solved, feeding and discharging efficiency of the glass is improved, and detection efficiency of glass thickness is improved.

2. According to the utility model, the effect of multipoint detection on glass is achieved by arranging the test frame, the screw rod A, the slide plate and the photoelectric sensor, and the motor A and the screw rod A drive the slide plate to move, so that the multipoint detection on the thickness of the glass is carried out, the problems that the multipoint detection effect on the glass is limited and the detection accuracy of the thickness of the glass is poor in the existing measuring mechanism are solved, the multipoint detection effect on the glass is improved, and the detection accuracy of the thickness of the glass is improved.

Drawings

FIG. 1 is a schematic diagram of a front view of the present utility model;

FIG. 2 is a schematic diagram of the front view of the positioning rack and the testing rack of the present utility model;

FIG. 3 is a schematic side view of the detection frame of the present utility model;

fig. 4 is an enlarged schematic view of a in fig. 1.

Reference numerals: 1. an equipment stand; 2. a detection frame; 3. a support table; 4. a slide block; 5. a conveying belt A; 6. a support frame; 7. a positioning frame; 8. a detection table; 9. a conveying belt B; 10. a photoelectric sensor; 11. a screw rod A; 12. a display; 13. a slide plate; 14. a test rack; 15. a motor A; 16. a screw rod B; 17. a motor B; 18. an electric telescopic device; 19. a slide bar; 20. a suction cup; 21. glass; 22. a grabbing frame; 23. a detection hole; 24. and (5) supporting the rod.

Detailed Description

The technical scheme of the utility model is further described below with reference to the attached drawings and specific embodiments.

Example 1

As shown in fig. 1-4, in order to achieve the above object, the present utility model provides the following technical solutions: the utility model provides a thickness check out test set that glass production used, including equipment table 1 and detection platform 8, install brace table 3 in the middle of the front surface of equipment table 1, install in the middle of equipment table 1 top and examine test table 8, conveyer belt A5 is installed to equipment table 1 top one side, be equipped with glass 21 in the middle of conveyer belt A5 top, equipment table 1 top deviates from conveyer belt A5 one side and installs conveyer belt B9, install electric telescopic 18 in the middle of the brace table 3 bottom, electric telescopic 18 output shaft top is installed and is examined test frame 2, detect and install lead screw B16 in the middle of the 2 inside of test frame, the slider 4 has been cup jointed in the middle of lead screw B16 surface, motor B17 is installed to lead screw B16 one end, install support frame 6 in the middle of the back surface, support frame 6 rear surface both sides all install the snatch frame 22, snatch frame 22 lower surface installs vacuum chuck 20 through bracing piece 24, all install slide bar 19 in the middle of the lower surface both sides of test frame 2, both sides 19 are pegged graft in the brace table 3 inside, be convenient for detect frame 2 steady movement, electric telescopic 18 is installed with the test frame 2 friction contact in the middle of the slider 4 rear surface and is located support frame 6 clearance position, install the slide bar 22 in two sets of two and two side position pairs of mutual position pairs of snatch 20 are convenient for the two and two side groups of snatch 20, two side position pairs of snatch 20 are convenient for snatch the two and two side groups of two side surface pairs of glass are equipped with two and two stable glass chuck 20, two position pairs of snatch hole pairs are convenient for snatch 20, two and two side position pairs of the glass 20 are convenient to snatch hole.

The thickness detection apparatus for glass production based on example 1 works on the principle that: after the utility model is installed, when glass is produced, the glass 21 is driven to move through the conveying belt A5, the glass 21 is moved to one side of the detection table 8, the electric telescopic device 18 is started, the grabbing frame 22 is driven to move downwards through the electric telescopic device 18, the vacuum chuck 20 is moved to the top of the glass 21, the vacuum chuck 20 is started again, the glass 21 at the top of the detection table 8 and the glass 21 at the top of the conveying belt B9 are simultaneously grabbed through the vacuum chuck 20, the electric telescopic device 18 is started again to drive the detection frame 2 to move upwards, the two-side glass 21 is driven to lift, after the completion, the motor B17 is started, the screw B16 is driven to rotate through the motor B17, the sliding block 4 is driven to move laterally through the screw B16, the supporting frame 6 is driven to move laterally through the sliding block 4, the grabbing frame 22 is driven to move laterally, the glass 21 at the top of the detection table 8 is moved to the top of the conveying belt B9, the glass 21 at the top of the conveying belt A5 is moved to the top of the detection table 8, and feeding and discharging are synchronously completed, so that the working flow of the device is completed.

Example two

As shown in fig. 1 to 4, the thickness detection apparatus for glass production according to the present utility model further includes: the locating rack 7 is installed near the middle of the rear surface at equipment platform 1 top, test rack 14 is installed through the connecting rod in the middle of the terminal lower surface of locating rack 7, lead screw A11 is installed in the middle of test rack 14 inside, lead screw A11 one end is located test rack 14 one side and installs motor A15, slide 13 has been cup jointed in the middle of the lead screw A11 surface, install photoelectric sensor 10 in the middle of the slide 13 lower surface, slide 13 top and test rack 14 frictional contact, install display 12 in the middle of the locating rack 7 top, display 12 and photoelectric sensor 10 electric connection.

In this embodiment, during detection, the motor a15 is started, the screw a11 is driven to rotate by the motor a15, the slide plate 13 is driven to move laterally by the screw a11, the photoelectric sensor 10 is driven to move by the slide plate 13, the thickness of the glass 21 is detected by the photoelectric sensor 10 at multiple points, and the detection data is displayed by the display 12.

The above-described embodiments are merely a few preferred embodiments of the present utility model, and many alternative modifications and combinations of the above-described embodiments will be apparent to those skilled in the art based on the technical solutions of the present utility model and the related teachings of the above-described embodiments.

Claims (7)

1. Thickness check out test set that glass production used, including equipment table (1) and detection platform (8), its characterized in that: install brace table (3) in the middle of the front surface of equipment table (1), install in the middle of equipment table (1) top and examine test table (8), conveyer belt A (5) are installed to equipment table (1) top one side, be equipped with glass (21) in the middle of conveyer belt A (5) top, conveyer belt B (9) are installed to equipment table (1) top one side of deviating from conveyer belt A (5), install electric telescopic ware (18) in the middle of brace table (3) bottom, detection frame (2) are installed at electric telescopic ware (18) output shaft top, install lead screw B (16) in the middle of detection frame (2) inside, slider (4) have been cup jointed in the middle of lead screw B (16) surface, motor B (17) are installed to lead screw B (16) one end, support frame (6) are installed in the middle of slider (4) rear surface, snatch frame (22) are all installed to support frame (6) rear surface both sides, snatch frame (22) lower surface and install vacuum chuck (20) through bracing piece (24).

2. The thickness detection apparatus for glass production according to claim 1, wherein: the device is characterized in that a locating frame (7) is arranged in the middle of the top of the device table (1) close to the rear surface, a test frame (14) is arranged in the middle of the lower surface of the tail end of the locating frame (7) through a connecting rod, a screw rod A (11) is arranged in the middle of the inside of the test frame (14), and a motor A (15) is arranged at one end of the screw rod A (11) and positioned at one side of the test frame (14).

3. A thickness detection apparatus for glass production according to claim 2, wherein: the device is characterized in that a sliding plate (13) is sleeved in the middle of the outer surface of the screw rod A (11), a photoelectric sensor (10) is mounted in the middle of the lower surface of the sliding plate (13), the top of the sliding plate (13) is in friction contact with a test frame (14), a display (12) is mounted in the middle of the top of the positioning frame (7), and the display (12) is electrically connected with the photoelectric sensor (10).

4. The thickness detection apparatus for glass production according to claim 1, wherein: the middle of two sides of the lower surface of the detection frame (2) is provided with a sliding rod (19), and the sliding rods (19) at two sides are inserted into the supporting table (3).

5. The thickness detection apparatus for glass production according to claim 1, wherein: the lower surface of the sliding block (4) is in friction contact with the detection frame (2), and an inclined stay bar is arranged at the clearance position of the supporting frame (6) on the rear surface of the sliding block (4).

6. The thickness detection apparatus for glass production according to claim 1, wherein: the two grabbing frames (22) are arranged in total, the two grabbing frames (22) are respectively arranged at two sides of the rear surface of the supporting frame (6), and detection holes (23) are respectively formed in the middle of the inner parts of the two grabbing frames (22).

7. The thickness detection apparatus for glass production according to claim 1, wherein: eight vacuum chucks (20) are arranged in total, the eight vacuum chucks (20) are equally divided into two groups, and the two groups of vacuum chucks (20) are respectively arranged at four corner positions of the lower surfaces of the two side grabbing frames (22).