CN111672663A - Tempered acrylic rhinestone processing equipment - Google Patents

Abstract

The invention discloses tempered acrylic rhinestone machining equipment which comprises a shell, a feeding hole, a feeding device, a material carrying plate, a rolling door, a tempering box, a tempering device and a collecting box, wherein the feeding hole is formed in the shell; the material loading plate comprises an embedded frame, a first spring, a first moving plate, a material loading hole and a fixed table; the first moving plate is movably embedded in the embedded frame; the first spring connects the first moving plate 43 and the embedding frame; the cross section of the material carrying hole is the same as the shape of the bottom surface of the rhinestone, and the opening size of the material carrying hole is the same as the bottom area of the rhinestone; the size of the fixed table is the same as that of the material loading hole, and the fixed table is embedded with the material loading hole; according to the invention, the material loading plate is placed on the feeding device, and the acrylic rhinestones are automatically embedded on the material loading plate through the feeding device, so that the limiting of the acrylic rhinestones is realized; then will carry the flitch to the tempering incasement, further make tempering liquid dash full the tempering incasement for tempering liquid is even sprays on the ya keli scalds brill surface, has improved the effect that equipment preparation tempering yakeli scalds the brill.

Description

Tempered acrylic rhinestone processing equipment

Technical Field

The invention belongs to the technical field of acrylic rhinestones, and particularly relates to equipment for improving the machining efficiency of a tempered acrylic rhinestone.

Background

In the process of manufacturing a tempered acrylic rhinestone in the prior art, firstly, an acrylic material is placed in a forming die, then a layer of tempering liquid is smeared on the formed acrylic rhinestone, and then the smeared acrylic rhinestone is placed in an oven at 60 ℃ for baking to be tempered; the tempering is paintd to current acryl hot-fixed rhinestone, is that the workman is manual to carry out the spraying to it, has reduced work efficiency like this, and on the other hand because the manual work is paintd inhomogeneous and lead to the tempering effect to reduce.

Disclosure of Invention

The invention provides a processing device of a tempered acrylic hot-fix rhinestone, aiming at overcoming the defects of the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme: a tempered acrylic rhinestone machining device comprises a shell, a feed inlet, a feeding device, a material carrying plate, a rolling door, a tempering box, a tempering device and a collecting box, wherein the feed inlet is formed in the shell, the feeding device is arranged below the feed inlet, the material carrying plate is erected on the feeding device, the rolling door is arranged on the side edge of the feeding device, the tempering box is arranged on the side edge of the shell, the tempering device is arranged in the tempering box, and the collecting box is arranged on the tempering box; the material carrying plate comprises an embedded frame which can be erected on the feeding device, a first spring which is arranged in the embedded frame, a first moving plate which is arranged in the embedded frame, a material carrying hole which is arranged on the first moving plate and a fixed platform which is arranged in the material carrying hole; the first moving plate is movably embedded in the embedded frame; the first spring connects the first moving plate 43 and the embedding frame; the cross section of the material carrying hole is the same as the shape of the bottom surface of the rhinestone, and the opening size of the material carrying hole is the same as the bottom area of the rhinestone; the size of the fixed table is the same as that of the material loading hole, and the fixed table is embedded with the material loading hole.

Before the equipment is started, a material loading plate is placed on a feeding device; then the acrylic hot-fix rhinestones which are molded by injection are scattered on the material carrying plate through the feeding holes; then the feeding device drives the material carrying plate to start shaking, so that the acrylic hot-fix rhinestones scattered on the material carrying plate are shaken and fixed on the material carrying plate; then conveying the material carrying plate into a toughening box, further starting a toughening device, and uniformly spraying toughening liquid on the surface of the acrylic rhinestone; then, the acrylic rhinestones are sent into a baking oven to be baked, so that the acrylic rhinestones are tempered; the automatic charging of the acrylic rhinestone is realized through the arrangement of the feeding device, and the equipment tempering efficiency is improved; the acrylic rhinestones can be embedded on the material loading plate through the arrangement of the material loading plate, and are limited, so that the acrylic rhinestones are always kept with the bottom surfaces facing downwards, and the tempering liquid is uniformly sprayed on the surfaces of the rhinestones; on one hand, the tempering box is sealed through the arrangement of the rolling door, and the tempering liquid is prevented from splashing into the shell to influence the tempering of the acrylic rhinestone when the rhinestone is tempered; the tempering liquid is automatically sprayed on the surface of the acrylic rhinestone through the arrangement of the tempering device, so that the tempering efficiency of the equipment is improved; on the other hand, because automatic spraying is realized, the uniformity during spraying is further ensured, and the quality of the tempered acrylic hot-fix rhinestones is improved; the first moving plate is arranged, so that the material carrying plate can be driven to deform through the movement of the first moving plate, the hot drills in the material carrying holes are exposed in the tempering box, and the spraying effect is improved; the fixing of the hot-fix rhinestones is realized through the arrangement of the fixing table, the dislocation of the hot-fix rhinestones caused by the equipment during tempering is prevented, on one hand, the effect of spraying tempering liquid on the equipment is improved, and on the other hand, the hot-fix rhinestones can be in the material carrying holes when the first movable plate is reset after the spraying is finished; the automatic limiting of the acrylic rhinestone is realized through the arrangement of the material loading holes, so that the material loading efficiency is improved, and the toughening efficiency is improved; on the other hand, due to the special shape of the material carrying holes, a part of unqualified products can be filtered, so that the quality of the tempered acrylic hot-fix rhinestone is ensured.

The fixed platform comprises a fixed cylinder arranged on the embedded frame, a material loading platform arranged on the fixed cylinder, an adsorption ring arranged on the material loading platform, a second spring arranged on the side edge of the material loading platform, a sliding block arranged on the second spring and a driving mechanism arranged in the fixed cylinder; the fixed cylinder is arranged at the bottom of the embedded frame and is positioned below the material loading hole; the material loading platform fixed cross section moves relative to the material loading hole and the material loading hole; the longitudinal section of the sliding block is triangular and movably embedded on the material loading platform.

When the acrylic rhinestones are scattered on the material carrying plate, the acrylic rhinestones are embedded in the material carrying holes under the driving of the feeding device, and the bottom surfaces of the acrylic rhinestones are placed on the adsorption rings; after the material loading plate after the material loading is moved to the toughening box, starting a toughening device, and further driving the first moving plate to descend; at the moment, along with the descending of the first moving plate, the slide block is separated from the first moving plate firstly and then is in butt joint with the toughening device; then driving a driving mechanism to reduce air pressure in the fixed cylinder, so that the acrylic hot-fix rhinestones are adsorbed on the material carrying table; the adsorption of the acrylic hot-fix rhinestones is realized through the arrangement of the adsorption rings, so that the adsorption force of the acrylic hot-fix rhinestones is improved, the contact area of the acrylic hot-fix rhinestones and air is reduced, and the situation that the acrylic hot-fix rhinestones cannot be adsorbed when the driving mechanism runs is prevented; the first moving plate is sealed when moving downwards through the arrangement of the sliding block; prevent that tempering liquid from entering into equipment and carrying in the flitch, influence the tempering effect.

The driving mechanism comprises a piston arranged in the fixed cylinder, a one-way valve arranged on the piston, a third spring arranged below the piston and a supporting plate arranged on the side edge of the piston; the piston is movably embedded in the fixed cylinder and is positioned in the adsorption ring; the abutting plate is movably embedded on the side wall of the fixed cylinder.

When the first moving plate starts to move downwards, the first moving plate is firstly contacted with the abutting plate; the piston is further driven to move downwards, and the air pressure in the fixed cylinder is reduced; thereby enabling the acrylic hot-fix rhinestones to be adsorbed on the material carrying table; when the first moving plate moves upwards and resets after the tempering liquid is sprayed, a further third spring starts to act, the piston moves upwards, and meanwhile, the one-way valve is opened to enable the acrylic hot drill to lose adsorption force; the piston is arranged to drive the piston to reduce the air pressure in the fixed cylinder, so that the acrylic hot-fix rhinestone can be adsorbed on the material carrying table.

The feeding device comprises a vibrating machine arranged at the bottom of the shell, a plurality of groups of first clamps arranged on the vibrating machine, a material receiving plate arranged below the first clamps, and a discharge hole arranged on the shell; the first clamps are respectively arranged at four corners of the vibrating machine; the material receiving plate is located below the first clamp and is in butt joint with the material receiving port.

Before the equipment is started, the material carrying plate is erected on a first clamp, and further acrylic hot-fix rhinestones are scattered on the material carrying plate; then starting a vibrator, driving the material carrying plate to start vibration, and embedding a part of acrylic hot-fix rhinestones into the material carrying holes; the redundant acrylic rhinestones are vibrated to the material receiving plate, and then the acrylic rhinestones are discharged out of the equipment from the discharge hole to carry out secondary material loading; the automatic positioning of the material carrying plate is realized through the arrangement of the first clamp, so that the material carrying effect is improved; the excessive acrylic rhinestones are collected and recovered through the arrangement of the material receiving plate, so that the rhinestones are prevented from being damaged and the quality of the tempered acrylic rhinestones is prevented from being influenced; on the other hand makes things convenient for the workman to the collection of scalding the brill to carry the material screening once more, improved the efficiency of equipment tempering.

The first clamp comprises a fixed block arranged on the vibrating machine, a motor arranged on the fixed block, a first inclined block arranged in the fixed block, a fourth spring arranged on the first inclined block, a rack arranged on the first inclined block, a second inclined block arranged on the first inclined block, a fifth spring arranged on the second inclined block, a gear arranged on the second inclined block and a fixed block arranged on the gear; the four fixed blocks are respectively and fixedly arranged on four corners of the vibrating machine; the first inclined block can be embedded in the fixed block in a way of moving up and down, and the upper surface of the inclined block is an inclined plane; the fourth spring is connected with the first inclined block and the bottom surface of the fixed block; the rack is positioned on the inclined surface of the first inclined block; the second inclined block can be embedded in the fixed block in a left-right moving manner; the fifth spring is connected with the second inclined block and the side wall of the fixed block; the gear is rotatably embedded in the second inclined block and can be meshed with the rack.

Before the equipment is started, the loading plate is placed on the first inclined block, the motor is further driven, and the driving gear starts to rotate; when the gear rotates, the fixed block starts to rotate along with the gear, and the fixed plate is buckled on the material carrying plate; meanwhile, the gear drives the second inclined block to move transversely, so that the second inclined block is abutted against the material carrying plate, and further, the first inclined block starts to move downwards due to the movement of the second inclined block, so that the whole material carrying plate descends and is in contact with the vibrating machine; meanwhile, when the first material carrying plate is completely installed, the fourth spring begins to reset and leaves the vibrating machine; the second material carrying plate is further convenient to place; the transverse positioning of the material carrying plate is realized through the arrangement of the second inclined block, the stability of the material carrying plate is improved, the dislocation is avoided during vibration, and the material carrying effect is improved; the longitudinal fixation of the material carrying plate is realized through the arrangement of the fixed block, so that the stability of the material carrying plate is improved, the vibration amplitude of the material carrying plate is reduced, and the vibration material carrying effect is improved; the vibration frequency of the material carrying plate is reduced through the arrangement of the fourth spring, so that the situation that the acrylic hot-fix rhinestones vibrate out of the material carrying holes again due to the fact that the vibration frequency is too high is prevented, and the material carrying effect is reduced; meanwhile, the material carrying plate can be placed on the first inclined block under the condition that the vibration machine does not stop; the mechanism realizes that the loading plate is fixed longitudinally and transversely by one motor driving mechanism, thereby further improving the effect of vibrating loading;

the toughening device comprises a material storage box arranged on the toughening box, an atomizing spray head arranged below the material storage box, a second clamp arranged in the material storage box, a phase panel arranged on the first clamp and a material storage plate arranged below the first clamp; the material storage box is positioned above the steel flower box and is connected with the atomizing spray head; the embedded plate is movably embedded on the clamp and can be abutted against the material carrying plate; the material storage plate is fixedly arranged below the clamp and connected with the collecting box.

When the material carrying plate is fully embedded with the acrylic rhinestone, the material carrying plate enters a tempering box; further placing the material carrying plate on a second fixture, and fixing the material carrying plate; then starting the phase embedding plate, and further abutting the phase embedding plate against the first moving plate to enable the first moving plate to descend, and simultaneously exposing the surface of the acrylic hot-fix rhinestone in the tempering box; starting an atomization spray head to enable the tempering box to be filled with tempering liquid, and smearing the acrylic rhinestones; further redundant toughening liquid flows into the material storage plate through the phase embedding plate and flows into the collection box from the material storage plate; the arrangement of the phase embedding plate can drive the first moving plate to move downwards, so that the acrylic rhinestones are positioned above the phase embedding plate, and the tempering liquid which is not coated on the surfaces of the acrylic rhinestones can be guided to the material storage plate for secondary recycling; the arrangement of the atomizing spray head realizes that the steel flower box is filled with the toughening liquid, so that the toughening liquid can be uniformly sprayed on the surface of the rhinestone, and the toughening quality is improved; the toughening liquid is collected and guided through the arrangement of the material storage plate, so that the utilization rate of the toughening liquid is improved; the tempering can be uniformly and uniformly sprayed on the surface of the acrylic rhinestone through the device, so that the tempering effect is improved; meanwhile, the tempering cost is reduced by recycling the tempering liquid.

The embedded plate comprises a second moving plate arranged on the second clamp, an embedded hole starting to be embedded with the second moving plate, a groove formed in the lower end face of the second moving plate, and a diversion groove formed in the upper end face of the second moving plate; the second moving plate can be embedded on the second clamp in a vertically moving mode; the shape of the embedding hole is the same as that of the material loading hole, and the size of the embedding hole is the same as that of the material loading hole.

When the embedded plate moves downwards to abut against the first moving plate, the embedded hole is firstly in butt joint with the material loading hole, and the first moving plate is further driven to move downwards; at the moment, the sliding block is butted with the embedding hole, and the bottom surface of the further acrylic hot-fix rhinestone is flush with the embedding plate; the first moving plate is abutted through the arrangement of the second moving plate, and the first moving plate is driven to move downwards; the acrylic rhinestone is limited by the arrangement of the embedding holes, so that the displacement of the acrylic rhinestone caused by the displacement of the second movable plate is prevented, and the movement of the acrylic rhinestone is influenced when the first movable plate is reset; the contact area between the lower surface of the second moving plate and the first moving plate is reduced through the arrangement of the grooves, so that the first moving plate and the second moving plate can not be smoothly separated from each other under the influence of the suction force of air pressure.

The atomizing nozzle comprises an atomizing cylinder arranged at the bottom of the material storage box, a shutter assembly arranged on the atomizing cylinder, an arc plate arranged at the lower end of the atomizing cylinder, a spiral plate arranged on the arc plate, atomizing holes arranged on the arc plate, a rotary ball arranged below the arc plate, water outlet holes arranged on the rotary ball and an air pipe arranged on the atomizing cylinder; the arc board is rotatable to be inlayed in atomizing bobbin base portion, and the directional shutter group of arc surface of this arc board: the spiral plates are uniformly arranged on the surface of the arc plate along the circumferential direction of the arc plate; the air pipe points to the spiral plate.

Opening the air pipe, wherein firstly, the air drives the louver group to open, and simultaneously, the toughened liquid in the material storage box flows into the atomizing cylinder through the louver group; at the moment, as the gas is continuously blown into the tank toughening liquid, the spiral plate is firstly driven to start rotating, and the toughening liquid forms fog through further airflow; then the atomized liquid floats in the rotary ball, and the rotary ball is blown out by gas, so that the tempering tank is filled with tempering liquid; the arrangement of the shutter plate component realizes the sealing of the material storage box on one hand, and prevents gas from blowing into the material storage box to influence the falling of the toughening liquid on the other hand; the arrangement of the spiral plate realizes that the arc plate rotates through gas, so that atomized tempering liquid flows into the rotary ball through rotation on one hand, and the atomized tempering liquid in the rotary ball floats in the air on the other hand, so that the tempering liquid is prevented from colliding with the rotary ball and solidifying, and the atomization effect is improved; the arrangement of the rotating ball realizes that the periphery of the tempering tank can be uniformly sprayed when the tempering liquid is sprayed, so that the uniformity in the tempering tank is improved; the uniformity of acrylic hot-fix rhinestones sprayed by the equipment is further improved; the air pipe is arranged to atomize the tempering liquid and drive the spiral plate to rotate at the same time, so that the atomization effect is improved; the arrangement of the mechanism realizes the atomization effect of the toughening liquid, so that the toughening liquid is filled in the toughening box; the uniformity of the sprayed tempering liquid is further improved, so that the tempering effect is improved;

the louver group comprises a louver arranged on the atomizing cylinder, an air groove arranged in the wall of the atomizing cylinder, a rotating plate arranged in the air groove, a torsion spring arranged on the rotating plate and a bronchus arranged on the air groove; the shutter can synchronously rotate on the under-smashing atomizing cylinder; the rotating plate is rotatably embedded in the air groove and is connected with the shutter; one end of the bronchus is connected with the air groove, and the other end of the bronchus is connected with the air pipe.

When the gas pipe is opened, gas is blown into the gas tank from the branch gas pipe; further gas drives the rotating plate to rotate, and the rotating plate starts to drive the shutter to rotate at the moment; further opening the shutter; then the toughened liquid flows into the atomizing cylinder from the shutter; after the air pipe is closed, the torsion spring starts to act to drive the rotating plate to rotate and close the shutter, so that the material storage barrel is closed; the synchronous rotation of the louver is realized through the arrangement of the rotating plate, and the automation of the equipment is improved; the setting through this mechanism has realized that tempering liquid can be equipment again and open when atomizing and hold the feed cylinder and carry out the unloading, but self-closing when not atomizing prevents that tempering liquid from flowing into the atomizing cylinder by mistake.

In conclusion, the invention has the following advantages: firstly, the acrylic hot-fix rhinestones scattered on the material carrying plate are automatically embedded into the material carrying holes through a vibrating machine, so that the limiting is realized, and the toughening embedding and carrying efficiency of the equipment is improved; when the acrylic hot-fix rhinestone is further toughened, the second movable plate drives the first movable plate to move, so that the piston drives the material carrying table to generate suction to absorb the acrylic hot-fix rhinestone, and the acrylic hot-fix rhinestone is exposed in the toughening box; then, opening the air pipe, and driving the shutter to open through air so that the tempering liquid can flow into the atomizing cylinder; further atomizing the tempering liquid in the atomizing cylinder through gas, and spraying the tempering liquid into the tempering box, wherein the further atomized tempering liquid can be uniformly sprayed on the surface of the acrylic rhinestone; finally, feeding the sprayed hot-fix rhinestones into a baking oven for tempering; the process replaces manual spraying, so that the spraying efficiency is improved, and the spraying uniformity can be effectively ensured due to the automatic spraying of the tempering liquid; the quality of the tempered acrylic rhinestone is improved.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a left side view of the present invention.

Fig. 3 is a front view of the present invention.

Fig. 4 is a cross-sectional view taken along a-a of fig. 2 of the present invention.

Fig. 5 is a cross-sectional view taken along B-B of fig. 2 of the present invention.

Fig. 6 is a cross-sectional view taken along line C-C of fig. 3 of the present invention.

Fig. 7 is a cross-sectional view taken along line D-D of fig. 3 of the present invention.

Fig. 8 is a partial cross-sectional view of a material-carrying plate of the present invention.

Fig. 9 is a partial view of the invention at D in fig. 8.

Fig. 10 is an exploded view of the stationary stage of the present invention.

Fig. 11 is a partial view of the invention at C in fig. 7.

Fig. 12 is a top view of the phase panel of the present invention.

Fig. 13 is a bottom view of the phase panel of the present invention.

Fig. 14 is a partial view of B of fig. 6 in accordance with the present invention.

FIG. 15 is a partial view taken at A of FIG. 5 in accordance with the present invention.

Detailed Description

As shown in fig. 1-15, a tempered acrylic rhinestone processing device comprises a shell 1, a feed inlet 2, a feeding device 3, a material carrying plate 4, a rolling door 5, a tempering box 6 and a tempering device 7 collecting box 8; the material carrying plate 4 comprises an embedded frame 41, a first spring 42, a first moving plate 43, a material carrying hole 44 and a fixed table 45; the feed inlet 2 is arranged on the upper end surface of the shell 1, and the opening is vertical to the bottom surface of the shell 1; the feeding device 3 is arranged in the shell 1 and is positioned right below the feeding hole 2; the material carrying plate 4 is arranged on the feeding device 7 in a detachable manner; the tempering box 6 is arranged on the side edge of the shell 1 and fixedly connected with the shell 1; the toughening device 7 is arranged in the toughening box 6; the collecting box 8 is arranged on the tempering box 6; the embedded frame 41 is detachably erected and provided with the feeding device 3; the first moving plate 43 is movably embedded in the embedded frame 41; the first spring 42 is connected with the first moving plate 43 and the embedded frame 41; the cross section of the material loading hole 44 is the same as the shape of the bottom surface of the rhinestone, and the opening size of the material loading hole 44 is the same as the bottom area of the rhinestone; the material loading holes 44 are uniformly arranged on the surface of the first moving plate 43; the fixed table 45 is the same as the loading hole 44 in size and is movably embedded with the loading hole 44.

As shown in fig. 8 to 10, the fixing table 45 includes a fixing cylinder 451, a material loading table 452, an adsorption ring 453, a second spring 454, a slider 455, and a driving mechanism 10; the fixed barrel 451 is arranged at the bottom of the embedding frame 41 and is positioned below the material loading hole 44; the cross section of the material loading platform 452 moves relative to the material loading hole 44 and moves relative to the material loading hole 44; the adsorption ring 453 is made of rubber and is fixedly arranged on the material loading table 452; the longitudinal section of the sliding block 455 is triangular, and the sliding block is movably embedded in the side wall of the material loading table 452; the second spring 454 connects the slider 455 and the material loading platform 452; the drive mechanism 10 is provided in the fixed cylinder 451.

As shown in fig. 10, the driving mechanism 10 includes a piston 101, a check valve 102, a third spring 103, and a resisting plate 104; the piston 101 is movably embedded in the fixed cylinder 451 and is positioned in the adsorption ring 453; the one-way valve 102 is arranged on the upper end surface of the piston 101, and the one-way valve 102 is directly available in the market; the third spring 103 is connected with the piston 101 and the bottom of the fixed cylinder 451; the resisting plate 104 is movably embedded on the side wall of the fixed cylinder 451 and is fixed on the piston 101.

As shown in fig. 3-4, the feeding device 3 includes a vibrator 31, a first clamp 32, a material receiving plate 33, and a material outlet 34; the vibrator 31 is arranged at the bottom of the shell 1, and the vibrator 31 is directly available in the market; the first clamps 32 are 4 groups and are respectively and fixedly arranged at 4 corners of the vibrator 31 and are vertical to the bottom surface of the shell 1; the material receiving plate 33 is positioned below the first clamp 32 and is butted with the material receiving port 34; the discharge port 34 is opened on the side wall of the shell 1.

As shown in fig. 7 and 11, the first clamp 32 includes a fixing block 321, a motor 322, a first inclined block 323, a fourth spring 324, a rack 325, a second inclined block 326, a fifth spring 327, a gear 328, and a fixing block 329; the number of the fixing blocks 321 is 4, and the fixing blocks are respectively fixedly arranged on 4 corners of the vibration 31 machine and are vertical to the bottom of the shell 1; the motor 322 is arranged on the side wall of the fixed block 321 and connected with the gear 328, and the motor 322 is directly available in the market; the first inclined block 323 can be embedded in the fixed block 321 in a way of moving up and down, and the upper surface of the first inclined block 323 is an inclined surface; the fourth spring 324 is connected with the first inclined block 323 and the bottom surface of the fixed block 321; the rack 325 is positioned on the inclined surface of the first inclined block 323; the second inclined block 326 can be embedded in the fixed block 321 in a left-right moving manner; the fifth spring 327 is connected to the second inclined block 326 and the side wall of the fixed block 321; the gear 328 is rotatably embedded in the second inclined block 326, and the gear 328 can be meshed with the rack 325; the fixing block 329 is disposed on the gear 328 and can be embedded with the first moving plate 43.

As shown in fig. 4, the toughening device 7 includes a storage box 71, an atomizing nozzle 72, a second clamp 73, an embedding plate 74, and a storage plate 75; the material storage box 71 is positioned above the tempering box 6 and is connected with an atomizing nozzle 72; the atomizing nozzle 72 is arranged above the material storage box 71 and is positioned in the toughening box 6; the number of the second clamps 73 is 4, and the second clamps 73 are respectively and fixedly arranged on 4 corners in the tempering box 6, and the structure of the second clamps 73 is the same as that of the first clamps 32; the phase panel 74 is movably embedded on the second clamp 73 and can be abutted against the material carrying plate 4; the material storage plate 75 is fixedly arranged below the second clamp 73 and connected with the collecting box 8.

As shown in fig. 12 to 13, the phase plate 74 includes a second moving plate 741, a phase fitting hole 742, a slot 743 and a guiding slot 744; the second moving plate 741 is vertically movable and is mounted on the second clamp 73; the shape of the embedding hole 742 is the same as that of the loading hole 44, and the size of the embedding hole 742 is the same as that of the loading hole 44, and the embedding holes 742 are uniformly formed in the second moving plate 741; the slot 743 is formed in the lower end face of the second moving plate 741; the guide groove 744 is opened on the upper surface of the second moving plate 741.

As shown in fig. 5-6 and 14, the atomizer 72 includes an atomizer tube 721, a louver assembly 20, a circular arc plate 722, a spiral plate 723, atomizer holes 727, a rotary ball 724, a water outlet hole 725 and an air pipe 726; the atomizing cylinder 721 is arranged at the bottom of the material storage box 71; the louver assembly 20 is disposed on the atomizing barrel 721; the arc plate 722 is rotatably embedded at the bottom of the atomizing cylinder 721, and the arc surface of the arc plate 722 points to the louver group 20; the spiral plate 723 is uniformly arranged on the surface of the arc plate 722 along the circumferential direction of the arc plate; the atomization holes 727 are formed in the surface of the arc plate 722 and are positioned between the adjacent 2 spiral plates 723; the rotating ball 724 is fixedly arranged on the arc plate 722; the water outlet holes 725 are uniformly formed in the surface of the rotating ball 724; the air pipe 726 is disposed on the atomizing cylinder 721, and the air pipe 726 points to the air pipe 726 and the spiral plate 723.

As shown in fig. 6 and 15, the louver group 20 includes a louver 201, an air groove 202, a rotating plate 203, a torsion spring 204, and a branch air pipe 205; the shutter 201 can be synchronously rotated and is embedded on the atomizing barrel 721; the gas tank 202 is arranged on the atomizing cylinder 721; the rotating plate 722 is rotatably embedded in the air groove 202 and is connected with the shutter 201; one end of the gas branch pipe 205 is connected with the gas groove 202, the other end is connected with the gas pipe 726, and the gas branch pipe 205 points to the rotating plate 203.

The specific working process is as follows: before the equipment is started, the material loading plate 4 is placed on the first inclined block 323, the motor 322 is further started, and the driving gear 328 starts to rotate; when the gear 328 rotates, the fixed block 329 rotates along with the gear 328, and the fixed plate 329 is buckled on the material carrying plate 4; meanwhile, the gear 328 drives the second inclined block 326 to move transversely, so that the second inclined block 326 abuts against the material carrying plate 4, and further, the first inclined block 323 starts to move downwards due to the movement of the second inclined block 326, so that the whole material carrying plate 4 descends and is in contact with the vibrator 31; then, the acrylic rhinestone is scattered on the material carrying plate 4 through the feeding hole 2, and the vibrating machine 31 is started; further vibrating the material loading plate 4; the acrylic rhinestones scattered on the material carrying plate 4 are embedded into the material carrying holes 44 under vibration; meanwhile, the rest acrylic hot-fix rhinestones are vibrated to fall on the material receiving plate 33, and then are discharged out of the equipment from the material outlet 34 to be collected to prepare for carrying materials for the second time; at the moment, the material loading plate 4 is fully loaded with acrylic hot-fix rhinestones; further conveying the material carrying plate 4 into the toughening box 6, and opening the rolling door 5 at the moment to enable the material carrying plate 4 to enter the toughening box 6 through the shell 1; further, the material loading plate 4 is positioned on a second clamp 73; starting the second moving plate 741 to move downward, and further the second moving plate 741 abuts against the first moving plate 43; first, the first moving plate 43 starts to move downwards, and the further slider 455 is separated from the first moving plate 43 and embedded with the second moving plate 741; at this time, the second moving plate 741 continues to move downward; the first moving plate 43 is brought into contact with the abutting plate 104; the piston 101 is driven to move downwards, and the air pressure in the fixed cylinder 451 is reduced; so that the acrylic rhinestone is adsorbed on the material loading table 452; at the moment, the bottom surface of the acrylic rhinestone is flush with the upper surface of the second moving plate 741; the gas pipe 726 is opened, and further gas is blown into the gas tank 202 from the gas branch pipe 205; further gas drives the rotating plate 203 to rotate, and at the moment, the rotating plate 203 starts to drive the shutter 201 to rotate; further opening the shutter 201; then, the toughened liquid flows into the atomizing barrel 451 from the shutter; at this time, as the gas is continuously blown into the tank tempering liquid, the spiral plate 723 is driven to start rotating, and the tempering liquid forms mist through the gas flow; then the atomized liquid floats in the rotating ball 724, and the gas blows out the rotating ball 724 to ensure that the toughening box 6 is filled with toughening liquid; at the moment, the tempering liquid is uniformly sprayed on the surface of the acrylic rhinestone; meanwhile, the redundant tempering liquid flows into the material storage plate 75 through the guide groove 744; the toughened liquid further flows into the collecting box 8 through the material storage plate to be collected; when the equipment stops spraying the tempering liquid, the gas outlet of the bronchus 205 is stopped firstly; further, the torsion spring 204 starts to act to drive the rotating plate 203 to rotate, so that the shutter 201 is closed, and the material storage barrel 71 is closed; the toughening liquid stops flowing into the atomizing cylinder 451; meanwhile, the second moving plate 741 is started to move upwards again for resetting; at this time, the first moving plate 43 loses the extrusion force, and the first spring 42 starts to act to drive the first moving plate 43 to move upwards for resetting; simultaneously, the third spring 103 starts to act to drive the piston 101 to reset upwards; at the moment, the one-way valve 102 is opened, so that the hot drill loses adsorption force; the further hot drill is embedded into the loading hole 44 under the movement of the first moving plate 43; then, the loading plate is put into an oven at 60 ℃ for baking to be toughened; thereby obtaining the toughened acrylic rhinestone.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (9)

1. A tempered acrylic rhinestone processing device comprises a shell (1), a feeding hole (2) formed in the shell (1), a feeding device (3) arranged below the feeding hole (2), a material carrying plate (4) erected on the feeding device (3), a rolling door (5) arranged on the side edge of the feeding device (4), a tempering box (6) arranged on the side edge of the shell (1), a tempering device (7) arranged in the tempering box (6) and a collecting box (8) arranged on the tempering box (7); the method is characterized in that: the material carrying plate (4) comprises an embedded frame (41) which can be erected on the feeding device (3), a first spring (42) which is arranged in the embedded frame (41), a first moving plate (43) which is arranged in the embedded frame (41), a material carrying hole (44) which is arranged on the first moving plate (43) and a fixed platform (45) which is arranged in the material carrying hole (44); the first moving plate (43) is movably embedded in the embedded frame (41); the first spring (42) is connected with the first moving plate (43) and the embedded frame (41); the cross section of the material loading hole (44) is the same as the shape of the bottom surface of the rhinestone, and the opening size of the material loading hole (44) is the same as the bottom area of the rhinestone; the size of the fixed platform (45) is the same as that of the material loading hole (44), and the fixed platform is embedded with the material loading hole (44).

2. The tempered acrylic rhinestone processing apparatus according to claim 1, wherein: the fixing platform (45) comprises a fixing barrel (451) arranged on the embedded frame (41), a material loading platform (452) arranged on the fixing barrel (451), an adsorption ring (453) arranged on the material loading platform (452), a second spring (454) arranged on the side edge of the material loading platform (452), a sliding block (455) arranged on the second spring (454), and a driving mechanism (10) arranged in the fixing barrel (451); the fixed barrel (451) is arranged at the bottom of the embedded frame (41) and is positioned below the material loading hole (44); the cross section of the material loading platform (452) moves relative to the material loading hole (44) and moves relative to the material loading hole (44); the longitudinal section of the sliding block (455) is triangular, and the sliding block is movably embedded on the material loading platform (452).

3. The tempered acrylic rhinestone processing apparatus according to claim 2, wherein: the driving mechanism (10) comprises a piston (101) arranged in the fixed cylinder (451), a one-way valve (102) arranged on the piston (101), a third spring (103) arranged below the piston (101), and a supporting plate (104) arranged on the side edge of the piston (101); the piston (101) is movably embedded in the fixed cylinder (451) and is positioned in the adsorption ring (453); the butt plate (104) is movably embedded on the side wall of the fixed cylinder (451).

4. The tempered acrylic rhinestone processing apparatus according to claim 1, wherein: the feeding device (3) comprises a vibrating machine (31) arranged at the bottom of the shell (1), a plurality of groups of first clamps (32) arranged on the vibrating machine (31), a material receiving plate (33) arranged below the first clamps (32), and a material outlet (34) arranged on the shell (1); the first clamps (32) are arranged at four corners of the vibrating machine (31) in four groups; the material receiving plate (33) is located below the first clamp (32) and is in butt joint with the material receiving opening (34).

5. The tempered acrylic rhinestone processing apparatus according to claim 4, wherein: the first clamp (32) comprises a fixed block (321) arranged on the vibrator (31), a motor (322) arranged on the fixed block (321), a first inclined block (323) arranged in the fixed block (321), a fourth spring (324) arranged on the first inclined block (323), a rack (325) arranged on the first inclined block (323), a second inclined block (326) arranged on the first inclined block (323), a fifth spring (327) arranged on the second inclined block (326), a gear (328) arranged on the second inclined block (326) and a fixed block (329) arranged on the gear (328); the four fixing blocks (321) are respectively and fixedly arranged on four corners of the vibration machine (31); the first inclined block (323) can be embedded in the fixed block (321) in a way of moving up and down, and the upper surface of the first inclined block (323) is an inclined surface; the fourth spring (324) is connected with the first inclined block (323) and the bottom surface of the fixed block (321); the rack (325) is positioned on the inclined surface of the first inclined block (323); the second inclined block (326) can be embedded in the fixed block (321) in a left-right moving manner; the fifth spring (327) is connected to the second inclined block (326) and the side wall of the fixed block (321); the gear (328) is rotatably embedded in the second swash block (326), and the gear (328) can be meshed with the rack (325).

6. The tempered acrylic rhinestone processing apparatus according to claim 1, wherein: the toughening device (7) comprises a material storage box (71) arranged on the toughening box (6), an atomizing spray head (72) arranged below the material storage box (71), a second clamp (73) arranged in the material storage box (71), a phase panel (74) arranged on the second clamp (73), and a material storage plate (75) arranged below the second clamp (74); the material storage box (71) is positioned above the tempering box (6) and is connected with the atomizing nozzle (72); the phase panel (74) is movably embedded on a second clamp (73) and can be abutted against the material carrying plate (4); the material storage plate (75) is fixedly arranged below the second clamp (73) and is connected with the collection box (8).

7. The tempered acrylic hot-fix drilling processing equipment according to claim 6, wherein the phase panel (74) comprises a second moving plate (741) arranged on the second clamp (73), an embedding hole (742) formed on the second moving plate (741), a slot (743) formed on the lower end face of the second moving plate (741), and a guide groove (744) formed on the upper end face of the second moving plate (741); the second moving plate (741) can be vertically moved and is embedded on the second clamp (73); the shape of the embedding hole (742) is the same as that of the loading hole (44), and the size of the embedding hole (742) is the same as that of the loading hole (44).

8. The tempered acrylic rhinestone processing apparatus according to claim 6, wherein the atomizing nozzle (72) comprises an atomizing cylinder (721) disposed at the bottom of the storage tank (71), a louver assembly (20) disposed on the atomizing cylinder (721), an arc plate (722) disposed at the lower end of the atomizing cylinder (721), a spiral plate (723) disposed on the arc plate (722), atomizing holes (727) disposed on the arc plate (722), a rotary ball (724) disposed under the arc plate (723), a water outlet (725) disposed on the rotary ball (724), and an air pipe (726) disposed on the atomizing cylinder (721); the arc plate (722) can be rotatably embedded at the bottom of the atomizing cylinder (721), and the arc surface of the arc plate (722) points to the louver group (20): the spiral plate (723) is uniformly arranged on the surface of the arc plate (722) along the circumferential direction of the arc plate; the air tube (726) is directed towards the spiral plate.

9. The tempered acrylic rhinestone processing apparatus according to claim 8, wherein: the louver group (20) comprises a louver (201) arranged on the atomizing cylinder (721), an air groove (202) arranged in the wall of the atomizing cylinder (721), a rotating plate (203) arranged in the air groove (202), a torsion spring (204) arranged on the rotating plate (203), and a branch air pipe (205) arranged on the air groove (202); the shutter (201) can be synchronously rotated and is embedded on the atomizing barrel (721); the rotating plate (722) is rotatably embedded in the air groove (202) and is connected with the shutter (201); one end of the bronchus (205) is connected with the air groove (202), and the other end is connected with the air pipe (726).

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