CN111735690A - Toughened glass quality detection equipment - Google Patents

Abstract

The invention discloses toughened glass quality detection equipment, which comprises a box body, wherein a main cavity with a right opening is arranged in the box body, a crumb detection and adjustment device is arranged in the main cavity and can automatically adjust the size standard of crumb according to the thickness of different toughened glass samples, a compression-resistant detection device for testing the strength of toughened glass and crushing and granulating the toughened glass is arranged on the upper side of the crumb detection and adjustment device, a crumb transfer device for transferring the toughened glass crumb is arranged on the lower side of the crumb detection and adjustment device, the crumb transfer device can transfer fragments in sequence according to the size, a crumb sorting device for detecting the quality of toughened glass particles is arranged on the lower side of the crumb transfer device, a crumb counting device for counting the number of the toughened glass crumb positioned on the left side of the crumb transfer device is arranged on the upper side of the crumb sorting device, the counting is accurate.

Description

Toughened glass quality detection equipment

Technical Field

The invention relates to the technical field of new material detection, in particular to toughened glass quality detection equipment.

Background

The toughened glass has the advantages that obtuse-angle particles generated after fragmentation do not hurt people, the compressive strength is high, the tensile strength is strong, and the like, the toughened glass quality is mainly detected by three groups of data, one group is the pressure of a fragmentation critical point of the toughened glass, the other group is the larger mass of ten particles in the toughened glass fragments, the other group is the number of particles after the toughened glass is fragmented in unit area, the detection of the toughened glass is mostly carried out in a laboratory at present, the automation level and the precision are not high enough, and the invention discloses equipment capable of solving the problems.

Disclosure of Invention

The technical problem is as follows: lack the equipment that a ability automated inspection toughened glass quality at present

In order to solve the above problems, the present embodiment designs a tempered glass quality detection device, which includes a box body, a main cavity with a right opening is arranged in the box body, an air pump is fixedly connected to an upper side end face of the box body, a display screen is fixedly connected to a right side end face of the box body, a granule detection adjusting device is arranged in the main cavity, the granule detection adjusting device includes two upper limiting plates fixedly connected to a rear inner wall of the main cavity, the two upper limiting plates are bilaterally symmetrical, four right dislocation shafts are respectively arrayed on lower sides of the upper limiting plates, the right dislocation shafts are rotatably connected between a front inner wall and a rear inner wall of the main cavity, a dislocation wheel is fixedly connected to a surface of the right dislocation shaft, a left limiting plate and a right limiting plate are fixedly connected to a rear end face of the main cavity, the right limiting plate is located on the left and right side limiting plates, four broken grain outlet grooves which are communicated left and right are arranged on the right limiting plate, an upper dislocation belt is fixedly connected between the dislocation wheels, the upper dislocation belt is connected in the left limiting plate in a sliding manner, the upper dislocation belt is connected in the broken grain outlet grooves in a sliding manner, a lower dislocation belt is connected on the lower side end surface of the upper dislocation belt in a sliding manner, the lower dislocation belt is fixedly connected between the left limiting plate and the right limiting plate, a plurality of grids which are communicated up and down are uniformly arranged in the lower dislocation belt and the upper dislocation belt in an array manner, a group of the upper dislocation belt which is attached is consistent with the grid specification on the lower dislocation belt, the grid specifications of different upper dislocation belts are inconsistent, the grid area on the first upper dislocation belt is the largest from top to bottom, the grid area on the second upper dislocation belt is larger, and the grid area on the third upper dislocation belt is smaller, the fourth piece go up on the dislocation area net area is minimum, left four the axle dislocation of a left side is on the surface respectively rotary gear of fixedly connected with, and is left fixedly connected with slip rack on the end face of slip nut plate right side, slip rack sliding connection in on the total cavity left side inner wall, granule detects adjusting device upside and is equipped with the resistance to compression detection device who is used for testing toughened glass intensity and with toughened glass granulation, granule detects the adjusting device downside and is equipped with the granule transfer device who is used for shifting the toughened glass granule, granule transfer device downside is equipped with the granule sorting device that detects the toughened glass granule quality, granule sorting device upside is equipped with and is located the left granule counting assembly who is used for toughened glass granule number count of granule transfer device.

Preferably, a rotating motor located on the lower side of the upper limiting plate on the left side is fixedly connected to the inner wall on the rear side of the main cavity, a left screw rod extending upward to the lower end surface of the upper limiting plate on the left side is dynamically connected to the upper side of the rotating motor, a right screw rod extending downward is rotatably connected to the lower end surface of the upper limiting plate on the right side, a rotating pulley is respectively connected to the surfaces of the left screw rod and the right screw rod, the two rotating pulleys are bilaterally symmetrical, a V-belt is connected between the two rotating pulleys, a sliding nut plate is respectively and spirally connected between the left screw rod and the right screw rod, the sliding nut plate on the right side is slidably connected to the inner wall on the right side of the main cavity, a sliding rack is fixedly connected to the end surface on the right side of the sliding nut plate on the left side of, the rotating gear is meshed with the sliding rack.

Preferably, the compression-resistant detection device comprises a torque motor fixedly connected to the inner wall of the upper side of the main cavity, the left side and the right side of the torque motor are respectively and dynamically connected with threaded rods extending to the inner walls of the left side and the right side of the main cavity in a direction away from the torque motor, the spiral directions of the two threaded rods are opposite, threaded sliders are spirally connected to the surfaces of the threaded rods, a lower pressing plate is arranged at the lower side of the torque motor, a connecting rod is hinged between the lower pressing plate and the threaded sliders, a pressure measuring plate is fixedly connected to the lower end surface of the lower pressing plate, vertical plates are fixedly connected to the upper end surface of the upper limiting plate, the two vertical plates are bilaterally symmetrical, a cylinder mounting plate is fixedly connected to the end surface of one side of the torque motor, a lower pressing cylinder is fixedly connected to the end surface of the lower side of, and a conical head piece is fixedly connected to the end surface of the lower side of the lower pressing air cylinder rod.

Preferably, the crumb transferring means includes an upward moving motor fixedly attached to the inner wall of the rear side of the general chamber, the upper side of the upward moving motor is dynamically connected with an upward moving lead screw which extends upwards, the surface of the upward moving lead screw is spirally connected with an upward moving slide block, a forward pushing cylinder is fixedly connected on the end face of the front side of the upper moving slide block, a forward pushing cylinder rod extending forwards is arranged in the forward pushing cylinder, the end surface of the front side of the front push cylinder rod is fixedly connected with a push plate, the end surface of the front side of the push plate is connected with a push block in a sliding way, the upper end surface of the push plate is fixedly connected with a fixed rack, the upper end surface of the push block is fixedly connected with a displacement motor, the upper side of the displacement motor is in power connection with a displacement motor shaft extending upwards, a displacement gear is fixedly connected to the end face of the upper side of the displacement motor shaft, and the displacement gear is in meshed connection with the fixed rack.

Preferably, the crumb sorting device comprises a transposition air cylinder fixedly connected to the inner wall of the lower side of the total cavity, a transposition air cylinder rod extending rightwards is arranged in the transposition air cylinder, a transposition plate is fixedly connected to the right end face of the transposition air cylinder rod, a weight measuring meter is fixedly connected to the upper end face of the transposition plate, a large crumb collecting part is fixedly connected to the upper end face of the weight measuring meter, a small crumb collecting body located on the right side of the weight measuring meter is fixedly connected to the upper end face of the transposition plate, a funnel mounting block located on the upper side of the transposition plate is fixedly connected to the inner wall of the rear side of the total cavity, and a funnel is fixedly connected to the front end face of the funnel mounting block.

Preferably, the counting device for the nibs comprises a downward moving motor fixedly connected to the inner wall of the upper side of the total cavity, the downward moving motor is positioned at the right side of the upper dislocation zone, the lower side of the downward moving motor is in power connection with a downward moving lead screw extending downward, a downward moving lead screw slider is in screw connection with the surface of the downward moving lead screw slider, an opening leftward guide pipe is fixedly connected to the front end face of the downward moving lead screw slider, a downward opening is simultaneously arranged on the guide pipe, an air pipe is pneumatically connected between the guide pipe and the air pump, a spring abutting rod is fixedly connected to the front end face of the total cavity, a mandrel is fixedly connected to the front end face of the total cavity, a ratchet shaft is fixedly connected to the front end face of the total cavity, a rotating plate is rotatably connected to the surface of the mandrel, a struck plate is fixedly connected to the left end face of the rotating plate, and the, the rotary plate and the spring abutting rod are connected through a return spring, a pawl cavity is formed in the left side of the rotary plate, and a pawl mounting block is arranged in the pawl cavity.

Preferably, the pawl installation block with be connected with the pawl spring between the inner wall of pawl chamber left side, fixedly connected with pawl on the pawl installation block right side end face, ratchet axle fixedly connected with ratchet on the surface, the ratchet claw number is ten, the pawl with the ratchet butt, even array has ten rotatory strips on the ratchet axle surface, rotatory strip is kept away from ratchet axle one side is equipped with rotatory strip chamber, rotatory strip intracavity is equipped with the striking rod, the striking rod with rotatory strip chamber is close to be connected with rotatory strip chamber spring between the inner wall of ratchet axle one side, fixedly connected with pipe on the total cavity rear side inner wall, the pipe upside is equipped with counting element.

The invention has the beneficial effects that: the broken grain detection and adjustment device can automatically adjust the standard of the size of the broken grains according to the thicknesses of different toughened glass samples, can effectively ensure that ten toughened glass broken grains with larger quality are obtained, the force applied to the toughened glass samples by the compression-resistant detection device is more stable, the toughened glass samples can be ensured to be broken and granulated, the broken grain transfer device can sequentially transfer broken grains according to the size, the broken grain sorting device can collect the former ten larger toughened glass broken grains firstly and then collect the rest toughened glass broken grains, and the broken grain counting device can effectively count by utilizing the falling force of the toughened glass.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic view of the overall structure of a tempered glass quality inspection apparatus according to the present invention;

FIG. 2 is an enlarged view of the structure at "A" in FIG. 1;

FIG. 3 is an enlarged view of the structure at "B" in FIG. 1;

FIG. 4 is an enlarged view of the structure at "C" of FIG. 1;

FIG. 5 is an enlarged view of the structure at "D" of FIG. 1;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1 to 6, for the sake of convenience of description, the following orientations are now defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a toughened glass quality detection device, which is mainly used for detecting the compressive strength of toughened glass and whether crushed particles are qualified, and the invention is further explained by combining the attached drawings of the invention:

the toughened glass quality detection equipment comprises a box body 11, wherein a main cavity 12 with a right opening is arranged in the box body 11, an air pump 29 is fixedly connected to the upper side end face of the box body 11, a display screen 23 is fixedly connected to the right side end face of the box body 11, a particle detection adjusting device 101 is arranged in the main cavity 12, the particle detection adjusting device 101 comprises two upper limiting plates 32 fixedly connected to the inner wall of the rear side of the main cavity 12, the two upper limiting plates 32 are bilaterally symmetrical, four right dislocation shafts 56 are respectively arrayed on the lower sides of the upper limiting plates 32, the right dislocation shafts 56 are rotatably connected between the inner wall of the front side and the inner wall of the rear side of the main cavity 12, dislocation wheels 54 are fixedly connected to the surfaces of the right dislocation shafts 56, a left limiting plate 51 and a right limiting plate 52 are fixedly connected to the end face of the rear side of the main cavity 12, the right limiting plate 52 is positioned on the right side of the, the right limit plate 52 is provided with four left and right through particle outlet grooves 57, an upper dislocation belt 59 is fixedly connected between the dislocation wheels 54, the upper dislocation belt 59 is connected in the left limit plate 51 in a sliding manner, the upper dislocation belt 59 is connected in the particle outlet grooves 57 in a sliding manner, a lower dislocation belt 58 is connected on the lower side end surface of the upper dislocation belt 59 in a sliding manner, the lower dislocation belt 58 is fixedly connected between the left limit plate 51 and the right limit plate 52, a plurality of grids 83 which are communicated up and down are uniformly arranged in the lower dislocation belt 58 and the upper dislocation belt 59 in an array manner, a group of the upper dislocation belts 59 and the grids 83 on the lower dislocation belt 58 are in the same specification, the grids 83 between the different upper dislocation belts 59 are in the different specifications, and from top to bottom, the first grid 83 on the upper dislocation belt 59 has the largest area, the area of the grid 83 on the second upper dislocation belt 59 is large, the area of the grid 83 on the third upper dislocation belt 59 is small, the area of the grid 83 on the fourth upper dislocation belt 59 is minimum, the surface of the left four left dislocation shafts 55 is fixedly connected with a rotating gear 53, the right end face of the sliding nut plate 31 on the left side is fixedly connected with a sliding rack 45, the sliding rack 45 is connected with the inner wall on the left side of the main cavity 12 in a sliding manner, the upper side of the granule detection and adjustment device 101 is provided with a pressure-resistant detection device 102 for testing the strength of the toughened glass and granulating the toughened glass, the lower side of the granule detection and adjustment device 101 is provided with a granule transfer device 103 for transferring the toughened glass granules, the lower side of the granule transfer device 103 is provided with a granule sorting device 104 for detecting the quality of the toughened glass granules, the upper side of the particle sorting device 104 is provided with a particle counting device 105 which is positioned on the left side of the particle transferring device 103 and is used for counting the number of the toughened glass particles.

Advantageously, a rotating motor 48 located at the lower side of the upper limiting plate 32 at the left side is fixedly connected to the inner wall at the rear side of the main chamber 12, a left screw 44 extending upward to the lower end surface of the upper limiting plate 32 at the left side is dynamically connected to the upper side of the rotating motor 48, a right screw 30 extending downward is rotatably connected to the lower end surface of the upper limiting plate 32 at the right side, one rotating pulley 46 is connected to the surface of each of the left screw 44 and the right screw 30, the two rotating pulleys 46 are bilaterally symmetrical, a V-belt 47 is connected between the two rotating pulleys 46, a sliding nut plate 31 is respectively screwed between the left screw 44 and the right screw 30, the sliding nut plate 31 at the right side is slidably connected to the inner wall at the right side of the main chamber 12, and a sliding rack 45 is fixedly connected to the end surface at the right side of the, the sliding rack 45 is slidably connected to the inner wall of the left side of the main cavity 12, the rotating gear 53 is engaged with the sliding rack 45, and the rotating motor 48 is controlled to work to drive the sliding nut plate 31 to move upwards to clamp the glass sample, so as to drive the sliding rack 45 to move upwards, and drive the rotating gear 53 to rotate clockwise, so as to drive the left dislocation shaft 55 to rotate clockwise, and drive the dislocation wheel 54 to rotate clockwise, so as to drive the upper dislocation belt 59 and the grids 83 on the lower dislocation belt 58 to be staggered, so as to implement different particle detection standards for glass samples with different thicknesses.

Beneficially, the compression-resistance detection device 102 comprises a torque motor 38 fixedly connected to the inner wall of the upper side of the total cavity 12, the left and right sides of the torque motor 38 are respectively and dynamically connected with threaded rods 35 extending away from the torque motor 38 to the inner walls of the left and right sides of the total cavity 12, the two threaded rods 35 have opposite spiral directions, the threaded rods 35 are spirally connected with threaded sliders 36 on the surface, a lower pressing plate 39 is arranged on the lower side of the torque motor 38, a connecting rod 37 is hinged between the lower pressing plate 39 and the threaded sliders 36, a pressure measuring plate 40 is fixedly connected to the end surface of the lower side of the lower pressing plate 39, vertical plates 33 are fixedly connected to the end surface of the upper side of the upper limiting plate 32, the two vertical plates 33 are bilaterally symmetrical, a cylinder mounting plate 34 is fixedly connected to the end surface of one side of the torque motor 38, and a lower pressing cylinder, a downward extending downward pressing air cylinder rod 42 is arranged in the downward pressing air cylinder 41, a conical head piece 43 is fixedly connected to the end face of the lower side of the downward pressing air cylinder rod 42, the threaded slide block 36 is driven to move towards the torque motor 38 by controlling the torque motor 38 to drive the lower pressing plate 39 to move downwards, after the pressure measuring plate 40 contacts the glass sample, the torque generated by the torque motor 38 is gradually increased, the pressure on the glass is continuously increased, the pressure measuring plate 40 records a sudden change value of the pressure, namely the pressure value when the glass sample is broken, and the pressure measuring plate 40 displays the numerical value on the display screen 23 after calculating the numerical value.

Advantageously, the crumb transferring device 103 comprises an upward moving motor 14 fixedly connected to the inner wall of the rear side of the total cavity 12, an upward moving screw 15 extending upward is connected to the upper side of the upward moving motor 14, an upward moving slider 64 is spirally connected to the surface of the upward moving screw 15, a forward pushing cylinder 65 is fixedly connected to the front end surface of the upward moving slider 64, a forward pushing cylinder rod 66 extending forward is arranged in the forward pushing cylinder 65, a push plate 49 is fixedly connected to the front end surface of the forward pushing cylinder rod 66, a push block 63 is slidably connected to the front end surface of the push plate 49, a fixed rack 50 is fixedly connected to the upper end surface of the push plate 49, a displacement motor 62 is fixedly connected to the upper end surface of the push block 63, an upward extending displacement motor shaft 61 is connected to the upper side of the displacement motor 62, a displacement gear 60 is fixedly connected to the upper end surface of the, the displacement gear 60 is meshed with the fixed rack 50, the upward moving sliding block 64 moves between the upper dislocation belts 59 by controlling the operation of the upward moving motor 14, the push plate 49 moves back and forth by controlling the operation of the forward push cylinder 65, and the push block 63 moves left and right by controlling the operation of the displacement motor 62, so that the transfer of the tempered glass particles is realized.

Advantageously, the cullet sorting device 104 comprises a transposition cylinder 13 fixedly connected to the inner wall of the lower side of the main cavity 12, a transposition cylinder rod 16 extending rightward is arranged in the transposition cylinder 13, a transposition plate 17 is fixedly connected to the right end face of the transposition cylinder rod 16, a weight measuring meter 18 is fixedly connected to the upper end face of the transposition plate 17, a large cullet collecting part 19 is fixedly connected to the upper end face of the weight measuring meter 18, a small cullet collecting body 22 positioned at the right side of the weight measuring meter 18 is fixedly connected to the upper end face of the transposition plate 17, a funnel mounting block 21 positioned at the upper side of the transposition plate 17 is fixedly connected to the inner wall of the rear side of the main cavity 12, a funnel 20 is fixedly connected to the front end face of the funnel mounting block 21, and by controlling the transposition cylinder 13 to work, larger toughened glass cullet falls into the large cullet collecting part 19, smaller tempered glass fragments fall into the small fragment collector 22.

Advantageously, the particle counting device 105 comprises a downward moving motor 28 fixedly connected to the inner wall of the upper side of the main chamber 12, the downward moving motor 28 is located at the right side of the upper dislocation belt 59, a downward moving screw 24 extending downward is connected to the lower side of the downward moving motor 28, a downward moving screw block 27 is spirally connected to the surface of the downward moving screw 24, an open leftward guide tube 25 is fixedly connected to the front end face of the downward moving screw block 27, the guide tube 25 is also provided with a downward opening, an air tube 26 is pneumatically connected between the guide tube 25 and the air pump 29, a spring pressing rod 67 is fixedly connected to the front end face of the main chamber 12, a mandrel 71 is fixedly connected to the front end face of the main chamber 12, a ratchet shaft 75 is fixedly connected to the front end face of the main chamber 12, a rotating plate 69 is rotatably connected to the surface of the mandrel 71, and a struck plate 70 is fixedly connected to the left end face of the rotating, the hit plate 70 is positioned at the lower side of the downward opening of the guide pipe 25, a return spring 68 is connected between the rotating plate 69 and the spring abutting rod 67, a pawl cavity 91 is formed in the left side of the rotating plate 69, and a pawl mounting block 73 is arranged in the pawl cavity 91.

Beneficially, a pawl spring 72 is connected between the pawl mounting block 73 and the inner wall of the left side of the pawl cavity 91, a pawl 74 is fixedly connected to the right end face of the pawl mounting block 73, a ratchet 76 is fixedly connected to the surface of the ratchet shaft 75, the number of the ratchet 76 is ten, the pawl 74 abuts against the ratchet 76, ten rotating strips 79 are uniformly arrayed on the surface of the ratchet shaft 75, a rotating strip cavity 80 is formed on one side of the rotating strip 79, which is far away from the ratchet shaft 75, a striking rod 82 is arranged in the rotating strip cavity 80, a rotating strip cavity spring 81 is connected between the striking rod 82 and the inner wall of the rotating strip cavity 80, which is close to the ratchet shaft 75, a round tube 77 is fixedly connected to the inner wall of the rear side of the total cavity 12, a counting element 78 is arranged on the upper side of the round tube 77, and the striking plate 70 is rotated downward by the force generated by falling tempered glass particles, the rotating plate 69 is driven to rotate, the pawl 74 is driven to buckle down and rotate upwards, after the particles fall from the hit plate 70, the rotating plate 69 and the pawl 74 are reset, the ratchet wheel 76 is driven to rotate for one tenth of a circle, the hitting rod 82 hits the counting element 78 once, and the counting of the particles is completed once.

The following describes in detail the use steps of a tempered glass quality detection apparatus herein with reference to fig. 1 to 6: initial state: the sliding nut plate 31 is located at the maximum clamping thickness limit position, the threaded slide block 36 is located at the two side limit positions, the push plate 49 is located at the lower limit position, the downward moving lead screw slide block 27 is located at the upper limit position, the conical head piece 43 is in a contraction state, the large particle collection position 19 is located at the lower side of the hopper 20, and the forward push cylinder rod 66 is in a contraction state.

During operation, manual putting toughened glass sample on the terminal surface of the side of slip nut plate 31, control the work of rotating electrical machines 48, slip nut plate 31 rebound is to pressing from both sides tight sample, and simultaneously, slip rack 45 rebound, drive rotatory gear 53 and rotate, thereby drive left dislocation axle 55 and rotate, thereby drive dislocation wheel 54 and rotate, make stagger between dislocation area 59 and the lower dislocation area 58 and form suitable opening, when the toughened glass sample of the different thickness of centre gripping, the opening size that forms is different, when the toughened glass sample of centre gripping thickness is great, the opening that forms is great, when the toughened glass sample of centre gripping thickness is less, the opening that forms is less, thereby obtain the screening standard of carrying out different to the produced bits of toughened glass of different thickness.

The torque motor 38 works to drive the threaded rods 35 on the two sides to rotate, so that the threaded sliders 36 on the two sides are driven to move towards the direction close to the torque motor 38, the lower pressing plate 39 moves downwards, the pressure measuring plate 40 automatically moves downwards to continuously and increasingly apply pressure to the toughened glass sample, and when the force changes suddenly, namely the toughened glass is broken, the pressure measuring plate 40 records the force before the force changes suddenly and calculates the pressure intensity to be output to the display screen 23 to obtain a first group of data.

The upper moving motor 14 works to drive the upper moving screw rod 15 to rotate, so as to drive the upper moving slide block 64 to move upwards to the uppermost upper dislocation belt 59, the lower moving motor 28 works to drive the lower moving screw rod 24 to rotate, so as to drive the lower moving screw rod slide block 27 to move downwards to the uppermost upper dislocation belt 59, the forward pushing cylinder 65 works, the forward pushing cylinder rod 66 extends out to push the tempered glass particles forwards, the displacement motor 62 works to drive the displacement motor shaft 61 to rotate, so as to drive the displacement gear 60 to rotate, so as to drive the pushing block 63 to move rightwards, so as to slowly push the tempered glass particles to the left opening of the right limiting plate 52, the air pump 29 starts working, the particles move along the track in the guide pipe 25 under the action of the suction force of the air pipe 26, the particles fall off, the force generated by falling of the tempered glass particles causes the hit plate 70 to rotate downwards, so as to drive the rotating plate 69 to rotate, so as to drive the pawl 74 to, after the particles fall from the hit plate 70, the rotating plate 69 and the pawl 74 are reset, so that the ratchet wheel 76 is driven to rotate for one tenth of a circle, the beating rod 82 beats the counting element 78 once, the particle counting is completed once, after the counting element 78 is beaten for ten times, the transposition air cylinder 13 works to drive the transposition air cylinder rod 16 to do rapid contraction movement, so that the small particle collector 22 moves to the lower side of the funnel 20, the weight meter 18 obtains the weight of the first ten particles and outputs the weight to the display screen 23 to obtain a second group of data, and the rest particles fall into the small particle collector 22.

The displacement motor 62 works, the push block 63 resets, the front push cylinder rod 66 resets, the upward moving motor 14 works, the upward moving lead screw 15 moves downwards to the next upper dislocation zone 59, meanwhile, the downward moving motor 28 works to drive the downward moving lead screw slide block 27 to move downwards, so that the guide pipe 25 is driven to move downwards to the next upper dislocation zone 59, the above actions are repeated until the particles all fall into the large particle collection part 19 and the small particle collection body 22, and the final counting reading is the third group of data.

The above steps are not sequentially performed, and a plurality of steps may be simultaneously performed.

The invention has the beneficial effects that: the broken grain detection and adjustment device can automatically adjust the standard of the size of the broken grains according to the thicknesses of different toughened glass samples, can effectively ensure that ten toughened glass broken grains with larger quality are obtained, the force applied to the toughened glass samples by the compression-resistant detection device is more stable, the toughened glass samples can be ensured to be broken and granulated, the broken grain transfer device can sequentially transfer broken grains according to the size, the broken grain sorting device can collect the former ten larger toughened glass broken grains firstly and then collect the rest toughened glass broken grains, and the broken grain counting device can effectively count by utilizing the falling force of the toughened glass.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims (7)

1. The utility model provides a toughened glass quality detection equipment, includes the box, its characterized in that: the garbage bin is characterized in that a main cavity with a rightward opening is arranged in the bin body, an air pump is fixedly connected to the end face of the upper side of the bin body, a display screen is fixedly connected to the end face of the right side of the bin body, a garbage detection and adjustment device is arranged in the main cavity and comprises two upper limiting plates fixedly connected to the inner wall of the rear side of the main cavity, the two upper limiting plates are bilaterally symmetrical, four right dislocation shafts are respectively arrayed on the lower sides of the upper limiting plates and rotatably connected between the inner wall of the front side and the inner wall of the rear side of the main cavity, dislocation wheels are fixedly connected to the surfaces of the right dislocation shafts, a left limiting plate and a right limiting plate are fixedly connected to the end face of the rear side of the main cavity, the right limiting plate is located on the right side of the left limiting plate, four garbage outlet grooves which are left-right communicated are arranged on the right limiting plate, and an, the upper dislocation belt is connected in the left limiting plate in a sliding manner, the upper dislocation belt is connected in the crushed particle outlet groove in a sliding manner, the lower lateral end face of the upper dislocation belt is connected with a lower dislocation belt in a sliding manner, the lower dislocation belt is fixedly connected between the left limiting plate and the right limiting plate, a plurality of grids which are communicated from top to bottom are uniformly arranged in the lower dislocation belt and the upper dislocation belt in an array manner, a group of attached upper dislocation belts and grids on the lower dislocation belt are consistent in specification, the grids between different upper dislocation belts are inconsistent in specification, from top to bottom, the grid area on a first upper dislocation belt is the largest, the grid area on a second upper dislocation belt is larger, the grid area on a third upper dislocation belt is smaller, the grid area on a fourth upper dislocation belt is the smallest, and four left dislocation shafts are respectively and fixedly connected with a rotating gear on the surface, it is left fixedly connected with slip rack on the slip nut board right side end face, slip rack sliding connection in on the total cavity left side inner wall, the crushed grain detects adjusting device upside and is equipped with the resistance to compression detection device who is used for testing toughened glass intensity and with toughened glass broken grain, crushed grain detects the adjusting device downside and is equipped with the crushed grain transfer device who is used for shifting the toughened glass crushed grain, crushed grain transfer device downside is equipped with the crushed grain sorting device who detects toughened glass granule quality, crushed grain sorting device upside is equipped with and is located the left crushed grain counting assembly who is used for toughened glass crushed grain number count of crushed grain transfer device.

2. The tempered glass quality detecting apparatus as claimed in claim 1, wherein: the inner wall of the rear side of the main cavity is fixedly connected with a rotating motor positioned on the lower side of the upper limiting plate on the left side, the upper side of the rotating motor is in power connection with a left screw rod extending upwards to the lower end face of the upper limiting plate on the left side, the lower end face of the upper limiting plate on the right side is in rotating connection with a right screw rod extending downwards, the surfaces of the left screw rod and the right screw rod are respectively connected with a rotating belt wheel, the two rotating belt wheels are in bilateral symmetry, a V belt is connected between the two rotating belt wheels, a sliding nut plate is respectively in screw connection between the left screw rod and the right screw rod, the sliding nut plate on the right side is in sliding connection with the inner wall of the right side of the main cavity, a sliding rack is fixedly connected on the end face of the right side of the sliding nut, the rotating gear is meshed with the sliding rack.

3. The tempered glass quality detecting apparatus as claimed in claim 1, wherein: the compression-resistant detection device comprises a torque motor fixedly connected to the inner wall of the upper side of the main cavity, the left side and the right side of the torque motor are respectively and dynamically connected with threaded rods extending to the inner wall of the left side and the right side of the main cavity in a direction away from the torque motor, the spiral directions of the two threaded rods are opposite, threaded sliders are spirally connected to the surfaces of the threaded rods, a lower pressing plate is arranged at the lower side of the torque motor, a connecting rod is hinged between the lower pressing plate and the threaded sliders, a pressure measuring plate is fixedly connected to the lower end face of the lower pressing plate, vertical plates are fixedly connected to the upper end face of the upper limiting plate and are bilaterally symmetrical, a cylinder mounting plate is fixedly connected to the end face of one side of the torque motor, a compression cylinder is fixedly connected to the lower end face of the cylinder mounting plate, and, and a conical head piece is fixedly connected to the end surface of the lower side of the lower pressing air cylinder rod.

4. The tempered glass quality detecting apparatus as claimed in claim 1, wherein: the particle transfer device comprises an upward moving motor fixedly connected to the inner wall of the rear side of the main cavity, the upper side of the upward moving motor is in power connection with an upward moving lead screw which extends upwards, the surface of the upward moving lead screw is in threaded connection with an upward moving slide block, the front end face of the upward moving slide block is fixedly connected with a forward pushing cylinder, a forward pushing cylinder rod which extends forwards is arranged in the forward pushing cylinder, the front end face of the forward pushing cylinder rod is fixedly connected with a push plate, the front end face of the push plate is in sliding connection with a push block, the upper side end face of the push plate is fixedly connected with a fixed rack, the upper side end face of the push block is fixedly connected with a displacement motor, the upper side of the displacement motor is in power connection with a displacement motor shaft which extends upwards, the upper side end face of the.

5. The tempered glass quality detecting apparatus as claimed in claim 1, wherein: the crumb sorting device comprises a transposition cylinder fixedly connected to the inner wall of the lower side of the total cavity, a transposition cylinder rod extending rightwards is arranged in the transposition cylinder, a transposition plate is fixedly connected to the right end face of the transposition cylinder rod, a weight measuring meter is fixedly connected to the end face of the upper side of the transposition plate, a large crumb collecting part is fixedly connected to the end face of the upper side of the weight measuring meter, a small crumb collecting body on the right side of the weight measuring meter is fixedly connected to the end face of the upper side of the transposition plate, a funnel mounting block on the upper side of the transposition plate is fixedly connected to the inner wall of the rear side of the total cavity, and a funnel is fixedly connected to the end face of the front side of the funnel mounting block.

6. The tempered glass quality detecting apparatus as claimed in claim 1, wherein: the particle counting device comprises a downward moving motor fixedly connected to the inner wall of the upper side of the total cavity, the downward moving motor is positioned on the right side of the upper dislocation zone, the lower side of the downward moving motor is in power connection with a downward moving lead screw extending downwards, the surface of the downward moving lead screw is in screw connection with a downward moving lead screw slider, the front end face of the downward moving lead screw slider is fixedly connected with a leftward guide pipe with an opening, the guide pipe is simultaneously provided with a downward opening, an air pipe is pneumatically connected between the guide pipe and the air pump, the front end face of the total cavity is fixedly connected with a spring pressing rod, the front end face of the total cavity is fixedly connected with a mandrel, the front end face of the total cavity is fixedly connected with a ratchet shaft, the surface of the mandrel is rotatably connected with a rotating plate, the left end face of the rotating plate is fixedly connected with a struck plate, and the, the rotary plate and the spring abutting rod are connected through a return spring, a pawl cavity is formed in the left side of the rotary plate, and a pawl mounting block is arranged in the pawl cavity.

7. The tempered glass quality detecting apparatus as claimed in claim 1, wherein: pawl installation piece with be connected with the pawl spring between the inner wall of pawl chamber left side, fixedly connected with pawl on the pawl installation piece right side end face, ratchet axle fixedly connected with ratchet on the surface, the ratchet claw number is ten, the pawl with the ratchet butt, there are ten rotatory strips in the even array of ratchet axle on the surface, rotatory strip is kept away from ratchet axle one side is equipped with rotatory strip chamber, rotatory strip intracavity is equipped with the striking rod, the striking rod with rotatory strip chamber is close to be connected with rotatory strip chamber spring between the inner wall of ratchet axle one side, fixedly connected with pipe on the total cavity rear side inner wall, the pipe upside is equipped with counting element.

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