CN118209349B - Dust collector detection device - Google Patents

Abstract

The invention relates to the technical field of dust collector detection, in particular to a dust collector detection device, which comprises a shell, wherein a detection table is arranged above the shell, a test groove is formed in the detection table, a clamping assembly is fixed on one side of the top end of the detection table, an air cylinder is fixed at the bottom end of the inside of the clamping assembly and is fixedly connected with the top end of the detection table, a controller is arranged on one side, far away from the clamping assembly, of the top end of the detection table, a wide-angle camera is arranged on one side of the inside of the test groove, a spraying assembly is arranged below the detection table, and a residue recovery assembly is arranged below the test groove; through the inside blowing of vortex fan to the discharging pipe, make inhale the material shell and inhale the piece from the inside of storage case, the piece is spouted into the inside of test tank through the discharge opening, can simulate the scene that ground has rubbish, through setting up the piece that three storage case and inside are equipped with different external diameters, can realize the cleaning performance to dust catcher test different external diameter piece.

Description

Dust collector detection device

Technical Field

The invention relates to the technical field of dust collector detection, in particular to a dust collector detection device.

Background

The dust collector is a cleaning tool, can be used for sucking dust, dirt and sundries on the surfaces of floors, furniture, walls and the like, and can rotate through an internal fan to enable negative pressure to be generated at a suction head during operation of the dust collector, and the dust can be brought into the dust collector along with sucked air through the negative pressure, so that the working state of the dust collector can be detected after the dust collector is produced.

Some solutions for dust collector detection are also proposed in the prior art, such as a patent application publication CN114593928a discloses a dust collector test device, which implements automatic detection by providing a plurality of mechanisms.

According to the technical scheme, only the basic working state of the dust collector can be detected in the using process, the condition of the dust collector when sucking solid chips cannot be detected, and the suction effect of the dust collector when sucking chips with different sizes cannot be detected, so that the tested result is different from the using effect of the dust collector in a real using scene, and the dust collector needs to be integrally fixed on testing equipment before testing, and the operation is complicated.

Disclosure of Invention

Therefore, the invention aims to solve the technical problems of different test results and using effects and single detection content.

In order to solve the technical problems, the invention provides a dust collector detection device, which comprises a shell, wherein a detection table is arranged above the shell, a test groove is formed in the detection table, a clamping assembly is fixed on one side of the top end of the detection table, an air cylinder is fixed at the bottom end of the inside of the clamping assembly and fixedly connected with the top end of the detection table, a controller is arranged on one side, far away from the clamping assembly, of the top end of the detection table, a wide-angle camera is arranged on one side of the inside of the test groove, a spraying assembly is arranged below the detection table, and a residual material recovery assembly is arranged below the test groove.

In one embodiment of the invention, the material spraying assembly comprises a discharge hole arranged at one side of the detection table far away from the wide-angle camera, the discharge hole is communicated with the inside of the test groove, a discharge pipe is fixed at the bottom end of the detection table close to the discharge hole, air spraying pipes are fixed at two sides of the inside of the discharge pipe, an outlet of each air spraying pipe faces to the direction of the discharge hole, an eddy current fan is arranged in each air spraying pipe, a material sucking pipe is fixed at the bottom end of each discharge pipe, a material sucking shell is fixed at the bottom end of each material sucking pipe, and a material storage box is arranged inside the shell.

In one embodiment of the invention, a moving block is fixed at the top end of the suction shell, a threaded rod is connected to the inner thread of the moving block, a first motor is installed on one side of the inner part of the shell, and the end part of a rotating shaft of the first motor is fixedly connected with one end of the threaded rod.

In one embodiment of the invention, the bottom end of the storage box, which is close to one side of the material sucking shell, is provided with a material sucking opening, the inner diameter of the material sucking opening is matched with the inner diameter of the material sucking shell, one side of the top end of the storage box is provided with a material supplementing opening, and the three storage boxes are distributed in the shell at equal intervals.

In one embodiment of the invention, the residue recycling assembly comprises a conveyor belt arranged below a test groove, a first conveyor roller is arranged at one end inside the conveyor belt, a second conveyor roller is arranged at one end, far away from the first conveyor roller, inside the conveyor belt, the first conveyor roller and the second conveyor roller are rotatably connected to the bottom end of a detection table through a supporting plate, a second motor is arranged at one side, close to the second conveyor roller, of the bottom end of the detection table, a transmission gear is fixed at one end, close to the second motor, of the second conveyor roller, an output gear is fixed at the end part of a rotating shaft of the second motor, the second motor is in meshed connection with the transmission gear through the output gear, and a recycling hole is formed in one side, close to the first conveyor roller, of the test groove.

In one embodiment of the invention, the cleaning brush roller is rotatably connected in the recovery hole, gears are fixed on both sides of the cleaning brush roller, gears are also fixed on both sides of the first conveying roller, the cleaning brush roller and the first conveying roller are connected through the gears on both sides in a meshed manner, a material guide pipe is fixed at a position below the detection table, which is close to the recovery hole, and the material guide pipe is communicated with the inside of the recovery hole.

In one embodiment of the invention, a scraper is fixed on the inner side wall of the recovery hole, and the scraper is abutted against the outer surface of the cleaning brush roller.

In one embodiment of the invention, a screening frame is arranged below the detection table, movable arms are fixed on two sides of the screening frame, sliding grooves are formed in positions, close to the movable arms, of two sides of the lower part of the detection table, guide rods are fixed in the sliding grooves, the guide rods penetrate through the inner parts of the movable arms, springs are fixed on two ends of the movable arms, the springs are sleeved outside the guide rods, pushing rods are fixed on one side, close to the second conveying roller, of the movable arms, and eccentric blocks are fixed on two sides of the second conveying roller.

In one embodiment of the invention, three layers of sieve hoppers are arranged in the sieving frame, the three layers of sieve hoppers are arranged at equal intervals from the upper part to the lower part of the inside of the sieving frame from the large inside diameter to the small inside diameter, and the inside of the sieve hopper at the bottom end is solid.

In one embodiment of the invention, a receiving hopper is arranged below the three layers of the screening hoppers of the screening frame respectively, a feed back pipe is fixed at the bottom end of each receiving hopper, and the three receiving hoppers are respectively communicated with the top ends of the three storage tanks through the feed back pipe.

Compared with the prior art, the technical scheme of the invention has the following advantages:

According to the dust collector detection device, the vortex fan blows air into the discharging pipe, so that the suction shell sucks scraps from the inside of the storage box, the scraps are sprayed into the inside of the test groove through the discharging hole, a scene that garbage exists on the ground can be simulated, and the dust collector can be tested for cleaning effects of scraps with different outer diameters by arranging the three storage boxes and arranging the scraps with different outer diameters in the three storage boxes.

According to the dust collector detection device, the residual scraps can be recovered through the conveying belt, the scraps on the surface of the conveying belt can be cleaned through the cleaning brush roller, the recovered scraps are screened through the screening frame, the screened scraps are respectively guided into the storage box through the receiving hopper, and the scraps after testing can be reused through the recovered scraps.

Drawings

In order that the invention may be more readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof that are illustrated in the appended drawings.

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view of the internal structure of the tapping pipe according to the present invention;

FIG. 4 is a schematic view of the structure of the storage bin of the present invention;

FIG. 5 is a schematic view of the structure of the screen frame of the present invention;

FIG. 6 is a schematic view of the bottom structure of the inspection station of the present invention;

FIG. 7 is a schematic view showing the internal structure of the inspection station according to the present invention;

Fig. 8 is a schematic view of the structure of the conveyor belt of the present invention.

Description of the specification reference numerals: 1. a housing; 2. a detection table; 21. a test tank; 211. a wide angle camera; 212. a recovery hole; 22. a discharge hole; 23. a chute; 3. a clamping assembly; 31. a cylinder; 4. a controller; 5. a discharge pipe; 51. a gas lance; 511. a vortex fan; 52. a suction pipe; 53. a suction shell; 531. a moving block; 532. a threaded rod; 533. a first motor; 6. a storage bin; 61. a material suction port; 62. a feed back pipe; 63. a receiving hopper; 7. a screening frame; 71. a moving arm; 711. a push rod; 72. a guide rod; 73. a spring; 8. a conveyor belt; 81. a first conveying roller; 82. cleaning a brush roller; 821. a scraper; 83. a second conveying roller; 831. a transmission gear; 84. an eccentric block; 85. a second motor; 86. and a material guiding pipe.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the invention and practice it.

Referring to fig. 1-2, the dust collector detection device of the invention comprises a shell 1, a detection table 2 is arranged above the shell 1, a test groove 21 is formed in the detection table 2, a clamping component 3 is fixed on one side of the top end of the detection table 2, an air cylinder 31 is fixed on the bottom end of the inner part of the clamping component 3, the air cylinder 31 is fixedly connected with the top end of the detection table 2, a controller 4 is arranged on one side of the top end of the detection table 2 far away from the clamping component 3, a wide-angle camera 211 is arranged on one side of the inner part of the test groove 21, a spraying component is arranged below the detection table 2, and a residue recovery component is arranged below the test groove 21;

during operation, the produced dust collector needs to be detected to ensure that the suction performance meets the expected standard, before detection, the chips are sprayed into the test tank 21 through the spraying component, at the moment, the chips in the test tank 21 are shot through the wide-angle camera 211 and are transmitted to the controller 4, the controller 4 records the quantity of the chips in the test tank 21, then the suction nozzle of the dust collector is placed in the test tank 21, the supporting rod of the dust collector is fixed through the clamping component 3, then the dust collector is started to suck the chips in the test tank 21, then the clamping component 3 is driven to be lifted through the air cylinder 31, the suction nozzle of the dust collector is moved out of the test tank 21, then the chips in the test tank 21 are shot again through the wide-angle camera 211 and are transmitted to the controller 4, the controller 4 obtains the inside surplus piece quantity of test tank 21 through the image contrast analysis of twice shooting afterwards, obtain the dust collecting effect of dust catcher through surplus piece quantity, the piece of multiple different external diameters can be spouted to the material spraying subassembly, carry out many times test to the dust catcher and obtain the dust collecting effect of dust catcher to different external diameters piece, can realize more comprehensive more realistic test, when the inside piece of test tank 21 is not absorbed completely, can retrieve the piece through the piece is retrieved to the surplus, and the inside inhaled piece of dust catcher pours into the inside of test tank 21 after the test is accomplished, also accessible surplus material is retrieved the piece and is retrieved it, can retrieve the piece of different external diameters in corresponding storage container through the inside screening of surplus material is retrieved the piece of subassembly, the cost of reducible test.

Referring to fig. 3-7, in one embodiment of the present invention, the material spraying assembly includes a discharge hole 22 formed in the inner portion of the detection platform 2 and far from the wide-angle camera 211, the discharge hole 22 is communicated with the inner portion of the test tank 21, a discharge pipe 5 is fixed at a position of the bottom end of the detection platform 2 near the discharge hole 22, air spraying pipes 51 are fixed at both sides of the inner portion of the discharge pipe 5, an outlet of the air spraying pipe 51 faces the direction of the discharge hole 22, an eddy fan 511 is installed in the inner portion of the air spraying pipe 51, a suction pipe 52 is fixed at the bottom end of the discharge pipe 5, a suction shell 53 is fixed at the bottom end of the suction pipe 52, and a material storage box 6 is arranged in the outer shell 1;

At the beginning of the test, the chips need to be sprayed into the test tank 21, at this moment, the vortex fan 511 is started to rotate to enable the top end of the air ejector tube 51 to blow out air flow, the air ejector tube 51 blows out air flow to the inside of the discharge tube 5 to enable negative pressure to be generated in the area below the inside of the discharge tube 5, at this moment, the discharge tube 5 sucks air into the suction shell 53 through the suction tube 52, the suction shell 53 sucks air into the storage box 6, the chips in the storage box 6 are sucked into the inside of the discharge tube 5 along with the air, the discharge tube 5 blows air and the chips into the inside of the discharge hole 22, the discharge hole 22 sprays the air and the chips into the test tank 21, and the subsequent test can be facilitated.

Referring to fig. 3, in an embodiment of the present invention, a moving block 531 is fixed to the top end of a suction case 53, a threaded rod 532 is screwed inside the moving block 531, a first motor 533 is installed at one side inside a housing 1, and a rotating shaft end of the first motor 533 is fixedly connected to one end of the threaded rod 532;

After testing the scraps with one outer diameter, the position of the suction shell 53 needs to be moved to suck scraps with other outer diameters, at this time, the first motor 533 is started to drive the threaded rod 532 to rotate, the threaded rod 532 drives the moving block 531 to move, and the moving block 531 drives the suction shell 53 to move, so that the suction shell 53 can be moved from the position of one storage box 6 to the position of the other storage box 6.

Referring to fig. 4, in one embodiment of the present invention, a material suction port 61 is formed at the bottom end of the material storage tank 6 near one side of the material suction shell 53, the inner diameter of the material suction port 61 is matched with the inner diameter of the material suction shell 53, a material supplementing port is formed at one side of the top end of the material storage tank 6, three material storage tanks 6 are provided, and the three material storage tanks 6 are distributed at equal intervals inside the housing 1;

When the material sucking shell 53 is in butt joint with the material storing box 6, the material sucking shell is communicated with the material sucking openings 61, chips inside the material storing box 6 can be sucked through the material sucking openings 61, and the three material storing boxes 6 can store chips with three different outer diameters.

Referring to fig. 7 to 8, in one embodiment of the present invention, the residue recovery assembly includes a conveyor belt 8 disposed under a test tank 21, a first conveyor roller 81 is disposed at one end inside the conveyor belt 8, a second conveyor roller 83 is disposed at one end inside the conveyor belt 8, which is far from the first conveyor roller 81, the first conveyor roller 81 and the second conveyor roller 83 are rotatably connected to the bottom end of a detection table 2 through a support plate, a second motor 85 is mounted at one side of the bottom end of the detection table 2, which is close to the second conveyor roller 83, a transmission gear 831 is fixed at one end of the second conveyor roller 83, which is close to the second motor 85, an output gear is fixed at the end of a rotation shaft of the second motor 85, the second motor 85 is engaged with the transmission gear 831 through the output gear, and a recovery hole 212 is opened at one side of the test tank 21, which is close to the first conveyor roller 81;

When the scraps are not completely sucked in, the second motor 85 is started to drive the transmission gear 831 to rotate through the output gear, the transmission gear 831 rotates to drive the second conveying roller 83 to rotate, at the moment, the second conveying roller 83 drives the conveying belt 8 to roll below the test groove 21, and scraps inside the test groove 21 can be conveyed to the direction of the recovery hole 212 when the conveying belt 8 rolls.

Referring to fig. 6-8, in one embodiment of the present invention, a cleaning brush roller 82 is rotatably connected to the inside of the recovery hole 212, gears are fixed to both sides of the cleaning brush roller 82, gears are also fixed to both sides of the first conveying roller 81, the cleaning brush roller 82 and the first conveying roller 81 are engaged and connected through gears on both sides, a material guiding pipe 86 is fixed to a position below the detection table 2 near the recovery hole 212, and the material guiding pipe 86 is communicated with the inside of the recovery hole 212;

When the conveyor belt 8 rolls, the first conveyor roller 81 is driven to roll simultaneously, the first conveyor roller 81 drives the cleaning brush roller 82 to rotate through gears on two sides, the cleaning brush roller 82 rotates to clean scraps on the outer surface of the conveyor belt 8, the outer surface of the conveyor belt 8 can be kept clean, and the scraps can enter the inside of the material guide pipe 86.

Referring to fig. 8, in one embodiment of the present invention, a scraper 821 is fixed to the inner side wall of the recovery hole 212, and the scraper 821 is abutted against the outer surface of the cleaning brush roller 82;

during the sweeping of the cleaning brush roll 82, there may be debris trapped between the bristles, and the blade 821 may clean the bristles of the cleaning brush roll 82.

Referring to fig. 5 and 8, in one embodiment of the present invention, a screening frame 7 is disposed below the detection platform 2, moving arms 71 are fixed on both sides of the screening frame 7, sliding grooves 23 are formed on both sides of the lower side of the detection platform 2 near the moving arms 71, guide rods 72 are fixed inside the sliding grooves 23, the guide rods 72 penetrate through the inner parts of the moving arms 71, springs 73 are fixed on both ends of the moving arms 71, the springs 73 are sleeved outside the guide rods 72, push rods 711 are fixed on one side of the moving arms 71 near the second conveying rollers 83, and eccentric blocks 84 are fixed on both sides of the second conveying rollers 83;

The piece inside the guide pipe 86 drops in the inside of screening frame 7 from the below, drives eccentric block 84 rotation when second transfer roller 83 rotates, and eccentric block 84 rotates round and can promote push rod 711 once, and push rod 711 drives the removal arm 71 and slides in the inside of spout 23, and spring 73 can drive the removal arm 71 and reset, and the removal arm 71 drives screening frame 7 reciprocating motion, and screening frame 7 reciprocating motion can sieve the piece.

Referring to fig. 5, in one embodiment of the present invention, three layers of sieve hoppers are arranged inside the sieving frame 7, and the three layers of sieve hoppers are arranged at equal intervals from top to bottom inside the sieving frame 7 from large to small in sieve pore inner diameter, wherein the inside of the sieve hoppers at the bottom end is solid;

The first layer of screening hoppers of the screening frame 7 can screen the chips with the largest outer diameter, then the chips with relatively smaller outer diameters fall into the second layer of screening hoppers, the second layer of screening hoppers can screen the chips with relatively larger outer diameters, and the chips with the smallest outer diameters fall into the third layer of screening hoppers, so that the chips with different outer diameters can be screened apart.

Referring to fig. 4, in one embodiment of the present invention, a receiving hopper 63 is respectively disposed below three layers of sieve hoppers of the sieving frame 7, a feed back pipe 62 is fixed at the bottom end of the receiving hopper 63, and the three receiving hoppers 63 are respectively communicated with the top ends of the three storage tanks 6 through the feed back pipe 62;

The chips screened by the three screening hoppers fall into the three receiving hoppers 63 respectively and are conveyed into the three storage boxes 6 for storing different chips through the feed back pipes 62 for subsequent detection.

Working principle: during operation, the produced dust collector needs to be detected to ensure that the suction performance meets the expected standard, the chips need to be sprayed into the test tank 21 at the beginning of the test, at the moment, the vortex fan 511 is started to rotate to enable the top end of the air ejector tube 51 to blow out air flow, the air ejector tube 51 blows out air flow to the inside of the discharge tube 5 to enable negative pressure to be generated in the area below the inside of the discharge tube 5, at the moment, the discharge tube 5 sucks air into the suction shell 53 through the suction tube 52, the suction shell 53 sucks air into the storage box 6, the chips in the storage box 6 are sucked into the discharge tube 5 along with the air, the discharge tube 5 blows air and the chips into the inside of the discharge hole 22, and the discharge hole 22 sprays the air and the chips into the test tank 21;

Then shooting and transmitting the chips in the test tank 21 to the controller 4 through the wide-angle camera 211, analyzing the quantity of the chips in the test tank 21 by the controller 4, placing a dust collector suction nozzle in the test tank 21, fixing a supporting rod of the dust collector through the clamping component 3, starting the dust collector to suck the chips in the test tank 21, driving the clamping component 3 to lift through the air cylinder 31 to enable the suction nozzle of the dust collector to be moved out of the test tank 21, shooting and transmitting the chips in the test tank 21 again through the wide-angle camera 211 to the controller 4, comparing and analyzing the images shot twice, then obtaining the quantity of the residual chips in the test tank 21, obtaining the dust collection effect of the dust collector through the quantity of the chips, and displaying the measured result through the controller 4;

After testing the scraps with one outer diameter, the position of the suction shell 53 is required to be moved to suck scraps with other outer diameters, at the moment, the first motor 533 is started to drive the threaded rod 532 to rotate, the threaded rod 532 drives the moving block 531 to move, the moving block 531 drives the suction shell 53 to move, the suction shell 53 can be moved from the position of one storage box 6 to the position of the other storage box 6, the three storage boxes 6 can store scraps with three different outer diameters, and three tests can be realized by sucking scraps with different outer diameters;

When the chips in the test tank 21 are not completely sucked, the second motor 85 is started to drive the transmission gear 831 to rotate through the output gear, the transmission gear 831 rotates to drive the second conveying roller 83 to rotate, at the moment, the second conveying roller 83 drives the conveying belt 8 to roll below the test tank 21, the chips in the test tank 21 can be conveyed to the direction of the recovery hole 212 when the conveying belt 8 rolls, the first conveying roller 81 is driven to roll simultaneously when the conveying belt 8 rolls, the first conveying roller 81 drives the cleaning brush roller 82 to rotate through gears on two sides, the cleaning brush roller 82 rotates to clean the chips on the outer surface of the conveying belt 8, the outer surface of the conveying belt 8 can be kept clean, the chips enter the inside of the material guide pipe 86, the chips in the material guide pipe 86 drop into the screening frame 7 from the lower part, the eccentric block 84 is driven to rotate when the second conveying roller 83 rotates, the eccentric block 84 rotates for one turn to push the push rod 711 once, the push rod 711 drives the movable arm 71 to slide in the chute 23, the spring 73 can drive the movable arm 71 to reset, the movable arm 71 drives the sieving frame 7 to reciprocate, the sieving frame 7 can sieve the chips, the first layer of sieve hopper of the sieving frame 7 can sieve the chips with the largest outer diameter, then the chips with the relatively smaller outer diameter fall into the second layer of sieve hopper, the second layer of sieve hopper can sieve the chips with the relatively larger outer diameter, the chips with the smallest outer diameter fall into the third layer of sieve hopper, the separation of the chips with different outer diameters can be realized, the chips separated by the three sieve hoppers fall into the three receiving hoppers 63 respectively and are conveyed into the three storage tanks 6 storing the different chips through the return pipes 62, the chips sucked in the dust collector can be poured into the test tank 21 after the test is finished, the chips sucked in the dust collector can be recovered through the residual material recovery assembly, by recycling the debris into the corresponding storage container, the cost of testing may be reduced.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations and modifications of the present invention will be apparent to those of ordinary skill in the art in light of the foregoing description. It is not necessary here nor is it exhaustive of all embodiments. And obvious variations or modifications thereof are contemplated as falling within the scope of the present invention.

Claims (1)

1. A dust collector detection device, characterized in that: the automatic detection device comprises a shell (1), a detection table (2) is arranged above the shell (1), a test groove (21) is formed in the detection table (2), a clamping assembly (3) is fixed on one side of the top end of the detection table (2), an air cylinder (31) is fixed at the bottom end of the inner part of the clamping assembly (3), the air cylinder (31) is fixedly connected with the top end of the detection table (2), a controller (4) is arranged on one side, far away from the clamping assembly (3), of the top end of the detection table (2), a wide-angle camera (211) is arranged on one side, inside the test groove (21), of the detection table (2) is provided with a spraying assembly, and a residue recovery assembly is arranged below the test groove (21).

The material spraying assembly comprises a discharge hole (22) formed in the detection table (2) and far away from one side of the wide-angle camera (211), the discharge hole (22) is communicated with the inside of the test groove (21), a discharge pipe (5) is fixed at the bottom end of the detection table (2) close to the position of the discharge hole (22), air spraying pipes (51) are fixed on two sides of the inside of the discharge pipe (5), an outlet of each air spraying pipe (51) faces the direction of the corresponding discharge hole (22), an eddy current fan (511) is mounted in the air spraying pipe (51), a material sucking pipe (52) is fixed at the bottom end of each discharge pipe (5), a material sucking shell (53) is fixed at the bottom end of each material sucking pipe (52), and a material storage box (6) is arranged in the shell (1).

A moving block (531) is fixed at the top end of the suction shell (53), a threaded rod (532) is connected to the inner thread of the moving block (531), a first motor (533) is installed on one side of the inner part of the shell (1), and the end part of a rotating shaft of the first motor (533) is fixedly connected with one end of the threaded rod (532);

the bottom end of the storage box (6) close to one side of the material sucking shell (53) is provided with a material sucking opening (61), the inner diameter of the material sucking opening (61) is matched with the inner diameter of the material sucking shell (53), one side of the top end of the storage box (6) is provided with a material supplementing opening, the three storage boxes (6) are arranged in the shell (1) in an equidistant mode;

The waste recycling assembly comprises a conveying belt (8) arranged below a test groove (21), a first conveying roller (81) is arranged at one end inside the conveying belt (8), a second conveying roller (83) is arranged at one end, far away from the first conveying roller (81), inside the conveying belt (8), of the conveying belt, the first conveying roller (81) and the second conveying roller (83) are rotatably connected to the bottom end of a detection table (2) through a supporting plate, a second motor (85) is arranged at one side, close to the second conveying roller (83), of the bottom end of the detection table (2), a transmission gear (831) is fixed at one end, close to the second motor (85), of the second conveying roller (83), an output gear is fixed at the end of a rotating shaft of the second motor (85), the second motor (85) is connected with the transmission gear (831) in a meshed mode, and a recycling hole (212) is formed in one side, close to the first conveying roller (81), of the test groove (21).

The inside of the recovery hole (212) is rotationally connected with a cleaning brush roller (82), gears are fixed on two sides of the cleaning brush roller (82), gears are also fixed on two sides of the first conveying roller (81), the cleaning brush roller (82) and the first conveying roller (81) are connected through gear meshing on two sides, a material guide pipe (86) is fixed at a position, close to the recovery hole (212), below the detection table (2), and the material guide pipe (86) is communicated with the inside of the recovery hole (212);

a scraping plate (821) is fixed on the inner side wall of the recovery hole (212), and the scraping plate (821) is tightly attached to the outer surface of the cleaning brush roller (82);

The screening device is characterized in that a screening frame (7) is arranged below the detection table (2), movable arms (71) are fixed on two sides of the screening frame (7), sliding grooves (23) are formed in the positions, close to the movable arms (71), of two sides of the lower side of the detection table (2), guide rods (72) are fixed in the sliding grooves (23), the guide rods (72) penetrate through the movable arms (71), springs (73) are fixed at two ends of the movable arms (71), the springs (73) are sleeved outside the guide rods (72), pushing rods (711) are fixed on one side, close to the second conveying rollers (83), of the movable arms (71), and eccentric blocks (84) are fixed on two sides of the second conveying rollers (83);

Three layers of sieve hoppers are arranged in the sieving frame (7), and are arranged at equal intervals from the upper part to the lower part in the sieving frame (7) from the inside diameter of sieve holes to the inside diameter of sieve holes, wherein the inside of the sieve hopper at the bottom end is solid;

The three-layer screening hopper of screening frame (7) below is provided with one respectively and connects hopper (63), the bottom of receiving hopper (63) is fixed with feed back pipe (62), and three connect hopper (63) are linked together with three storage box (6) top respectively through feed back pipe (62).