CN215827110U - Defective product blanking assembly and inductance coil detection packaging device - Google Patents

Defective product blanking assembly and inductance coil detection packaging device Download PDF

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Publication number
CN215827110U
CN215827110U CN202120648988.8U CN202120648988U CN215827110U CN 215827110 U CN215827110 U CN 215827110U CN 202120648988 U CN202120648988 U CN 202120648988U CN 215827110 U CN215827110 U CN 215827110U
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assembly
block
groove
positioning
subassembly
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CN202120648988.8U
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黄立波
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Zhuhai Kefeng Electronics Co ltd
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Zhuhai Kefeng Electronics Co ltd
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Abstract

The utility model provides a defective product blanking assembly and an inductance coil detection and packaging device, wherein the defective product blanking assembly comprises a transfer assembly, a conveying assembly and a defective product classification assembly, the transfer assembly comprises a rotary table, and a plurality of positioning grooves are formed in the rotary table along the circumferential direction of the rotary table; a manipulator assembly in the conveying assembly moves between the transfer assembly and the defective product sorting assembly; the classified assembly of defective products includes ejector pad subassembly and classification dish, be provided with the categorised groove of a plurality of parallels on the classification dish, the ejector pad subassembly includes first mount pad, the ejector pad, push device and ejector pad removal subassembly, ejector pad and push device set up on first mount pad, the first mount pad of ejector pad removal subassembly drive removes along the array orientation in a plurality of classification grooves, the extension direction orientation classification groove removal in the push device drive ejector pad along classification groove, structure more than adopting, classify a plurality of bad products, avoid the wasting of resources, and rationally carry out the overall arrangement to the structure of unloading subassembly better, effectively improve work efficiency.

Description

Defective product blanking assembly and inductance coil detection packaging device
Technical Field
The utility model relates to the field of inductance coil manufacturing equipment, in particular to a defective product blanking assembly and an inductance coil detection and packaging device.
Background
After the winding of the framework is finished and the inductance coils are obtained, the huge number of inductance coils are required to be detected and packaged before shipment, so that the quality of the inductance coils during shipment is ensured. The coil detection device is characterized in that blanking is started after coil detection is completed, finished products are classified according to defective products and qualified products during blanking, and the qualified products are packaged and delivered. However, in the existing blanking process, defective products are directly stacked, the defective products are not classified and then are discarded uniformly, and certain resource waste is caused.
SUMMERY OF THE UTILITY MODEL
The first purpose of the utility model is to provide a defective product blanking assembly for classifying defective products.
The second purpose of the utility model is to provide an inductance coil detecting and packaging device comprising the defective product blanking assembly.
In order to achieve the first purpose, the defective product blanking assembly provided by the utility model comprises a transfer assembly, a conveying assembly and a defective product classification assembly, wherein the transfer assembly comprises a rotary table and a rotary table driving device, the rotary table driving device drives the rotary table to rotate, and a plurality of positioning grooves are formed in the rotary table along the circumferential direction of the rotary table; the conveying assembly comprises a manipulator assembly and a manipulator moving driving assembly, and the manipulator moving driving assembly drives the manipulator assembly to move between the transfer assembly and the defective product classification assembly; the defective product classification component comprises a push block component and a classification disc, a plurality of classification grooves are formed in the classification disc, the classification grooves are arranged in parallel, the push block component comprises a first mounting seat, a push block, a pushing device and a push block moving component, the push block and the pushing device are arranged on the first mounting seat, the push block moving component drives the first mounting seat to move along the arrangement direction of the classification grooves, a material pushing position is arranged on the first mounting seat, the material pushing position is arranged between the push block and the classification disc, and the pushing device drives the push block to move towards the classification grooves along the extension direction of the classification grooves.
According to the scheme, the control system in the blanking assembly classifies the classification grooves on the classification disc corresponding to different detection items of the inductance coils, for example, the inductance coils with unqualified electrical property detection are concentrated in the first classification groove, the inductance coils with unqualified appearance detection are concentrated in the second classification groove, when the inductance coils are blanked, the inductance coils which are detected are placed in the positioning grooves on the rotary disc one by one, the control system in the blanking assembly controls the rotary disc to rotate according to the detection result to drive the inductance coils on the rotary disc to move to the qualified product blanking position and the defective product blanking position, when the inductance coils on the rotary disc move to the defective product blanking position, the conveying assembly conveys the inductance to the material pushing position on the pushing block, the control system drives the first mounting seat to move to the corresponding classification groove according to the detection result, the pushing device drives the pushing block to move towards the classification groove, the induction coil in the material pushing position is pushed into the classification groove, and the defective products are classified, so that resource waste caused by uniform treatment after a plurality of defective products of different types are stacked together is avoided, and the analysis of defective reasons of different types of defective products by operators can be facilitated; through carousel drive inductance coils to passing article unloading department and defective products unloading, can carry out the unloading of passing article and defective products simultaneously for rationally carrying out the overall arrangement to the structure of unloading subassembly better, effectively improve work efficiency.
The manipulator assembly comprises a second mounting seat, a suction nozzle and a rotation stopping assembly, the suction nozzle and the rotation stopping assembly are respectively arranged on the second mounting seat, the rotation stopping assembly comprises a rotation stopping block and a positioning pin, an open slot is formed in the rotation stopping block, the positioning pin is located in the open slot, and the suction nozzle and the rotation stopping block are fixedly connected.
Therefore, when the conveying assembly moves between the turntable and the defective product classification assembly to transfer the inductance coil, the inductance coil is fixed through the suction nozzle, and the inductance coil is quickly fixed through suction force by the suction nozzle; the suction nozzle and the rotation stopping block are fixedly connected, and the positioning pin is located in an open slot of the rotation stopping block, so that the rotation stopping block cannot rotate, the suction nozzle cannot rotate all the time in the period of transferring the inductance coil, and the condition that the inductance coil falls from the suction nozzle is avoided.
The suction nozzle is provided with a suction opening, a positioning groove is formed in the suction nozzle, the positioning groove is provided with a first opening, a second opening and a third opening, the first opening, the second opening and the third opening are communicated with the positioning groove respectively, the first opening is arranged on one side, facing the suction nozzle, of the positioning groove, the second opening and the third opening are arranged oppositely, and the first opening is located between the second opening and the third opening.
It is thus clear that because conveying component passes through the fixed inductance coils of suction nozzle, first opening sets up towards the suction nozzle, and the suction nozzle passes first opening and takes away inductance coils, convenient and fast, and the stitch on the inductance coils runs through second opening and third opening correspondingly, and the stitch on the inductance coils extrudes in the constant head tank and warp.
The further scheme is that one end, facing the material pushing position, of the pushing block is provided with a positioning step, a positioning block and a positioning concave portion are formed on the positioning step, the positioning concave portion is adjacent to the material pushing position, and the positioning block is located above the positioning concave portion in the vertical direction.
Therefore, when the pushing block pushes the inductance coils in the material pushing position, the inductance coils are located in the positioning concave portion, and the positioning blocks are arranged on the positioning concave portion and limit the inductance coils in the positioning concave portion, so that the phenomenon that the inductance coils are placed inconsistently in the classification groove due to the fact that the inductance coils are turned on the side is avoided.
The further scheme is that a first limiting plate and a second limiting plate are arranged on the first mounting seat, the push block moves in a limiting groove between the first limiting plate and the second limiting plate, and the push block is located outside the limiting groove.
Therefore, the push block is located in the limiting groove between the first limiting plate and the second limiting plate, the first limiting plate and the second limiting plate guide the moving direction of the push block, and the accuracy of pushing the inductance coil by the push block is improved.
The further scheme is that each classification groove is provided with a side plate along the two sides of the extension direction of the classification groove, two positioning strips are arranged between the two side plates and arranged in parallel, the positioning strips extend along the extension direction of the classification grooves, and the protrusion heights of the side plates are higher than the protrusion heights of the positioning strips based on the bottom surfaces of the classification grooves.
Therefore, the arrangement of the side plates separates the two adjacent classification grooves, mutual collision of the inductance coils in the two adjacent classification grooves is avoided, the positioning strips support pins on the inductance coils, the framework parts of the inductance coils are located in the two positioning strips, and the inductance coils are kept in the classification grooves to move in a posture.
The classification groove comprises a feeding port and a baffle plate, the feeding port is arranged between the pushing block assembly and the baffle plate, a plurality of side plates are arranged between the feeding port and the baffle plate, an avoiding groove is arranged between the side plates and the baffle plate, and the avoiding groove is communicated with the classification groove; the classification plate is provided with an inductor, and the induction end of the inductor is opposite to the avoiding groove.
It can be seen that, because each classifying groove is provided with an avoiding groove near the baffle, the avoiding grooves of adjacent classifying grooves are communicated with each other, and the avoiding end of the inductor can detect whether each classifying groove is filled with the inductance coil or not through the avoiding groove.
In order to achieve the second object, the inductance coil detecting and packaging device provided by the utility model comprises the defective product blanking assembly.
Drawings
FIG. 1 is a schematic diagram of an embodiment of an apparatus for inspecting a package by an induction coil according to the present invention.
Fig. 2 is an enlarged view of fig. 1A.
FIG. 3 is a block diagram of a clamp assembly in an embodiment of an induction coil inspecting and packaging apparatus according to the present invention.
Fig. 4 is a block diagram of the reverse transport assembly in an embodiment of the induction coil inspecting and packaging apparatus of the present invention.
Fig. 5 is a block diagram of the components on the turning block in an embodiment of the induction coil detecting and packaging apparatus of the present invention.
Fig. 6 is a block diagram of a first conveyor assembly in an embodiment of an induction coil inspecting and packaging apparatus of the present invention.
Fig. 7 is an enlarged view at fig. 1B.
FIG. 8 is a partial block diagram of a direct vibration assembly in an embodiment of an induction coil inspecting packaging apparatus according to the present invention.
Fig. 9 is a block diagram of a turret assembly in an embodiment of an induction coil inspecting and packaging apparatus of the present invention.
Fig. 10 is a block diagram of another angle of the turret assembly in an embodiment of the induction coil detecting and packaging apparatus of the present invention.
Fig. 11 is a partial structural view of a second performance measuring unit in an embodiment of the induction coil measuring and packaging apparatus of the present invention.
FIG. 12 is a partial block diagram of a calibration assembly in an embodiment of the induction coil inspecting packaging apparatus of the present invention.
FIG. 13 is a partial block diagram of a lateral CCD detecting assembly in an embodiment of an inductive coil detecting packaging apparatus of the present invention.
Fig. 14 is an enlarged view at fig. 1C.
Fig. 15 is a structural view of a defective product sorting unit in the inductance coil inspecting and packaging apparatus according to the present invention.
Fig. 16 is an enlarged view of fig. 1D.
Fig. 17 is a block diagram of the marking vision assembly of the induction coil detecting and packaging apparatus of the present invention.
Fig. 18 is a structural view of a third conveyor assembly in the induction coil inspecting and packaging apparatus of the present invention.
Fig. 19 is a structural view of a rotation block in the inductance coil detecting and packaging apparatus according to the present invention.
Fig. 20 is a sectional view of a rotary block in the induction coil detecting and packaging apparatus of the present invention.
FIG. 21 is a block diagram of a packaging assembly in the induction coil inspecting packaging apparatus of the present invention.
FIG. 22 is a schematic diagram of a carrier tape heat press assembly of the induction coil inspecting and packaging apparatus of the present invention.
Fig. 23 is a structural view of a carrier tape pressing and conveying belt assembly in the inductance coil detecting and packaging apparatus of the present invention.
The utility model is further explained with reference to the drawings and the embodiments.
Detailed Description
The inductance coil detecting and packaging device is used for detecting and packaging the inductance coil, wherein the defective product blanking assembly serves as a transfer station through the rotary table, the rotary table and the mechanical arm assembly are matched to move defective products to the defective product blanking position, qualified products are moved to the qualified product blanking position, and the qualified products and the defective products can be simultaneously blanked, so that the structure of the blanking assembly can be better and reasonably arranged, and the working efficiency is effectively improved.
Referring to fig. 1, full-automatic inductance coils detects packing plant includes mount table 11, material loading subassembly 1, upset conveying subassembly 2, first conveying subassembly 3, first performance detection subassembly, detect capstan head subassembly 5, defective products unloading subassembly, second conveying subassembly 7 and packing subassembly 10, defective products unloading subassembly includes transfer subassembly 6, defective products classification component 8 and third conveying subassembly 9, mount table 11 is provided with installation terminal surface 111 along the horizontal direction, material loading subassembly 1, upset conveying subassembly 2, first conveying subassembly, first performance detection subassembly, directly shake subassembly 4, detect capstan head subassembly 5, transfer subassembly 6, defective products classification component 8, second conveying subassembly 7, third conveying subassembly 9 and packing subassembly 10 set up on installation terminal surface 111.
In this embodiment, the jig 12 is used to simultaneously load a plurality of inductor coils, thereby effectively improving the working efficiency. The jig 12 is in a long strip shape, a plurality of placing grooves 121 are arranged on the jig 12 along the length direction of the jig 12, and one placing groove 121 is used for placing one inductance coil.
The feeding assembly 1 comprises a first track assembly 13, a plug pin assembly 14, a feeding positioning assembly 15, a second track assembly 16 and a clamping assembly 17, wherein the first track assembly 13 comprises a first track 131 and a first track driving assembly, the first track driving assembly is used for driving the jig 12 on the first track 131 to move, and when the jig 12 is placed on the first track 12, the extending direction of the first track 131 is parallel to the length direction of the jig 12. The first rail 131 is sequentially provided with a material loading position, a material loading position and a material unloading position along the extending direction of the first rail 131. Bolt subassembly 14 sets up on first track 131, and bolt subassembly 14 sets up and waits to expect to be located the material loading between the material level is got in the material loading. Latch assembly 14 includes a latch 141 and a latch driver 142, latch driver 142 being an air cylinder. The bolt driving device 142 drives the bolt 141 to move towards the first track 131, and the axial direction of the bolt 141 is perpendicular to the extending direction of the first track 131. After the plug driving device 142 drives the plug 141 to move towards the first track 131, the plug 141 blocks the jig 12 in the feeding waiting position from moving to the feeding waiting position, so that the inductor coil on the jig 12 in the feeding and taking position has enough time to complete the feeding of the inductor coil. The jig 12 in the material loading and taking position completes the loading of the inductance coil, and the empty jig moves to the jig material unloading position.
In this embodiment, the feeding positioning assembly 15 includes two sets of positioning block assemblies, the two positioning block assemblies are arranged along the extending direction of the first rail 131, and the two positioning block assemblies are respectively corresponding to the two ends of the jig along the length direction of the jig for positioning. Referring to fig. 2, the positioning block assembly includes a first positioning block 151, a second positioning block 152, and a positioning block driving device 153, wherein the positioning block driving device 153 drives the first positioning block 151 to move toward or away from the second positioning block 152. When the positioning block driving device 153 drives the first positioning block 151 to move toward the second positioning block 152, the first positioning block 151 and the second positioning block 152 clamp one end of the fixture 12. In the present embodiment, the positioning block driving device 153 is a pneumatic chuck, and the positioning block driving device 153 drives the first positioning block 151 and the second positioning block 152 to move toward or away from each other. Two sets of locating piece subassemblies set up along the extending direction collineation of first track 131, and two sets of locating piece subassemblies correspond the both ends of tool 12 along the extending direction of first track 131 respectively, and the tight tool 12 of locating piece subassembly clamp makes tool 12 can't get the skew that removes or take place the position in the material position of material loading, improves the accuracy of getting the material.
The second rail assembly 16 comprises a second rail 161 and a second rail driving assembly 162, the second rail driving assembly 162 is used for driving the jigs on the second rail 161 to move, the first rail 131 is arranged in parallel with the second rail 161, the conveying direction of the first rail 131 is opposite to that of the second rail 161, the clamping assembly 17 is arranged between the first rail 131 and the second rail 161, and the clamping assembly 17 is used for moving the empty jigs on the jig blanking position of the first rail 131 to the second rail assembly 16. In this embodiment, the structure of the first track driving assembly is the same as that of the second track driving assembly 162, and the second track driving assembly 162 drives the driving belt to move through the motor, so as to drive the jig 12 in the second track 161 to move.
Referring to fig. 3, the clamping assembly 17 includes a clamping block assembly and a clamping block driving assembly, the clamping block driving assembly drives the clamping block assembly to move between the first rail 131 and the second rail 161, the clamping block assembly includes a first clamping block 171, a second clamping block 172 and a clamping block driving device 173, the first clamping block 171 and the second clamping block 172 are identical in structure, the clamping block driving device 173 is a pneumatic clamping jaw, and the clamping block driving device 173 drives the first clamping block 171 to move towards or away from the second clamping block 172, and simultaneously the clamping block driving device 173 drives the second clamping block 172 to move towards or away from the first clamping block 171. In this embodiment, the clamping block driving assembly includes a supporting frame 174, a linear air cylinder 175, a mounting block 176, and a driving air cylinder 170, the linear air cylinder 175 being disposed on the supporting frame 174, the linear air cylinder 175 driving the mounting block 176 to move in a horizontal direction, the driving air cylinder being disposed on the mounting block 176, the driving air cylinder driving the clamping block assembly to move in a vertical direction. Two convex blocks 177 are convexly arranged on the side wall of the first clamping block 171 facing the second clamping block 172, and an avoidance empty position 178 is formed between the two convex blocks 177. The clamping block assembly further comprises a first pressing block 179 and a second pressing block, the first pressing block 179 and the second pressing block are arranged in a collinear manner along the extending direction of the first rail 131, and the first pressing block 179 and the second pressing block are respectively arranged between the first clamping block 171 and the second clamping block 172. When the first clamping block 171 and the second clamping block 172 clamp the jig along the width direction of the jig 12, the first pressing block 179 and the second pressing block press the jig, so that the jig is more stable when moving between the first rail 131 and the second rail 161.
Upset conveyor components 2 is arranged in getting the inductance coils in the material level with the material loading of first track 131 and getting the material and the upset, and the inductance coils begins to detect after being convenient for first conveyor components get the material. Referring to fig. 4 and 5, the turnover conveying assembly 2 includes a fixed frame 21, a moving plate 22, a turnover block 23, a turnover driving assembly, a clamping assembly 24, a plurality of suction nozzles 25 and a suction nozzle mounting block 26, in this embodiment, the turnover driving assembly includes a rotary driving device 27 and a movable driving cylinder 28, the movable driving cylinder 28 is disposed on the fixed frame 21, the movable driving cylinder 28 drives the moving plate 22 to move along a vertical direction, the turnover block 23 and the rotary driving device 27 are respectively disposed on the fixed frame 21, a driving rod of the rotary driving device 28 penetrates through the moving plate 22 and then is connected to the turnover block 23, and the rotary driving device 28 drives the turnover block 23 to rotate. The grip assembly 24, the suction nozzle 25 and the nozzle mounting block 26 are respectively provided on the same side wall of the turning block 23.
The clamp assembly 24 includes a first clamp block 241, a second clamp block 242, and a clamp block drive 243, the clamp block drive 243 driving the first clamp block 241 towards or away from the second clamp block 242. In this embodiment, the clamp block driving device 243 is a pneumatic clamp jaw, and the clamp block driving device 243 drives the first clamp block 241 and the second clamp block 242 to move towards or away from each other along the first direction X respectively. The suction nozzle mounting block 26 is disposed between the first clamping block 241 and the second clamping block 242, and the plurality of suction nozzles 25 are disposed on a side wall of the suction nozzle mounting block 26 facing away from the turning block 23. When the overturning conveying assembly 2 transfers materials, the first clamping block 241 and the second clamping block 242 in the clamping assembly 24 clamp the inductance coil on the first rail 131, the suction nozzle 25 on the suction nozzle mounting block 26 sucks the inductance coil tightly in vacuum, the rotary driving device 27 drives the overturning block 23 to overturn for 180 degrees, the side wall of the overturning block 23 provided with the clamping assembly 24 faces upwards, and after the inductance coil is loosened by the first clamping block 241 and the second clamping block 242, the first conveying assembly takes materials. The stability of the inductor coil during the overturning process is enhanced by simultaneously fixing the inductor coil by the clamping assembly 24 and the suction nozzle 25.
The first supporting block 243 is convexly arranged on the side wall of the first clamping block 241 facing the second clamping block 242, the second supporting block 244 is convexly arranged on the side wall of the second clamping block 242 facing the first clamping block 241, and the first supporting block 243 and the second supporting block 244 are located on the same horizontal plane. The suction nozzle 25 may be disposed between the first support block 243 and the turning block 23 and between the second support block 243 and the turning block 23. The first supporting block 243 is far away from the turning block 23 at the first clamping block 241, the second supporting block 244 is far away from the turning block 23 at the first clamping block 241, so that a clamping portion 245 is formed between the first supporting block 243 or the second supporting block 244 and the turning block 23, the suction nozzle 25 fixes the inductance coil in the clamping portion 245, the inductance coil in the clamping portion 245 is limited by the first supporting block 243 and the second supporting block 244, the inductance coil is prevented from being separated or shifted in position from the first clamping block 241 and the second clamping block 242 under the clamping force of the first clamping block 241 and the second clamping block 242, and the stability of the inductance coil is further guaranteed. In this embodiment, a plurality of first avoiding grooves 246 are formed in the first support block 243 to divide the first support block 243 into a plurality of first small support blocks, and one first avoiding groove 246 is located between two adjacent first small support blocks. The second supporting block 244 is provided with a plurality of second avoiding grooves 247, the second supporting block 244 is divided into a plurality of second small supporting blocks, one second avoiding groove 247 is located between two adjacent first small supporting blocks, and the first avoiding groove 246 and the second avoiding groove 247 are oppositely arranged and communicated. The groove is avoided, a plurality of small supporting blocks are formed on the supporting blocks, the two small supporting blocks which are arranged oppositely correspondingly support an inductance coil, the protruding portion of the inductance coil is located in the groove, the shape of the inductance coil is better adapted, the limiting effect of the first supporting block 243 and the second supporting block 244 is better, and the clamping of the inductance coil is more stable.
A plurality of positioning blocks 248 are arranged between the first clamping block 241 and the second clamping block 242, one suction nozzle 25 correspondingly penetrates through one positioning block 248, the plurality of positioning blocks 248 are arranged in a collinear manner along the second direction Y, and the first direction X and the second direction Y can be intersected. The positioning block 248 is provided with a positioning groove 2481 on the side wall far away from the turning block 23, and the opening direction of the positioning groove 2481 deviates from the turning block 23. Due to the arrangement of the positioning groove 2481, a first positioning side plate 2482 and a second positioning side plate 2483 are respectively formed on the positioning block 248 at two sides of the positioning groove 2481, the first positioning side plate 2482 and the second positioning side plate 2483 are oppositely arranged along the second direction Y, a first inclined surface 2484 is arranged on the side wall of the first positioning side plate 2482 facing the second positioning side plate 2483, and the first inclined surface 2484 extends away from the second positioning side plate 2483; the second positioning side plate 2483 is provided with a second inclined surface 2485 on a side wall facing the first positioning side plate 2481, and the second inclined surface 2485 extends away from the first positioning side plate 2481. The arrangement of the first inclined surface 2484 and the second inclined surface 2485 enables the inductor to enter the positioning groove 2481 more quickly and accurately, and the suction nozzle 25 fixes the inductor in the positioning groove 2481, so that the stability of the inductor is further improved.
In this embodiment, a first mounting block 249 and a second mounting block are arranged on a cylinder of the clamp block driving device 243, the first mounting block 249 and the second mounting block are respectively connected with the suction nozzle mounting block 26, and the first mounting block 249 and the second mounting block are arranged along the second direction Y, so that the first mounting block 249 and the second mounting block are not in the moving direction of the first clamp block 241 and the second clamp block 242, interference on the movement of the first clamp block 241 and the second clamp block 242 is avoided, and the layout of components on the turning block 23 is more reasonable.
In this embodiment, the moving plate 22 is provided with the limiting column 221, the limiting column 221 and the turning block 23 are located on the same side wall of the moving plate 22, the limiting column 221 is arranged in the rotation direction of the turning block 23, the turning block 23 rotates 180 degrees and then abuts against the limiting column 221, and the arrangement of the limiting column 221 can control the rotation range of the turning block 23, so that the turning block 23 can keep the posture after turning 180 degrees when the first conveying assembly takes materials.
The moving plate 22 is further provided with a sensor 222, the sensor 222 is provided with a groove 223, the sensor 222 and the overturning block 23 are located on the same side wall of the moving plate 22, a detection plate 231 is arranged on the side wall of the overturning block 23, which is far away from the clamping assembly 24, and the detection plate 231 passes through the groove 223. The rotation of the turning block 23 drives the detection plate 231 to rotate, so that the detection plate 231 passes through the groove 223, and the sensor 222 can detect whether the turning block 23 turns in place or not.
The first conveyor assembly comprises a first robot conveyor assembly 3 and a direct vibration assembly 4, and in this embodiment, the first robot conveyor assembly 3 is disposed between the reversing conveyor assembly 2 and the inspection turret assembly 5. Referring to fig. 6, the first robot transport assembly 31 includes a first robot assembly 31 and a first driving assembly 32, and the first driving assembly 32 drives the first robot assembly 31 to move. The first robot assembly 31 includes a mounting block 311, a plurality of first nozzles 312, and a first rotation driving device 313, and the first rotation driving device 313 is a rotation motor. The plurality of first suction nozzles 312 are simultaneously arranged on the mounting block 311, the plurality of first suction nozzles 312 take materials simultaneously, and the plurality of inductance coils are loaded at one time, so that the working efficiency is improved; the first rotation driving device 313 drives the mounting block 311 to rotate along the horizontal plane. First drive assembly 32 drives first manipulator subassembly 31 along horizontal direction and vertical reverse movement, and first drive assembly includes horizontal rotation motor 321, horizontal lead screw 322, connecting block 323, vertical rotation motor 324 and vertical lead screw 325, and horizontal rotation motor 321 drives horizontal lead screw 322 and rotates, drives the connecting block 323 that is connected with horizontal lead screw 322 and removes, and vertical rotation motor 324 sets up respectively on connecting block 323 with vertical lead screw 325. The vertical rotating motor 324 drives the vertical screw rod 325 to rotate, drives the mounting block 326 connected with the vertical screw rod 325 to move, and the first manipulator assembly is arranged on the mounting block 326, so as to drive the first suction nozzle 312 to move.
Along the extending direction of horizontal lead screw 322, be provided with directly on the installation terminal surface 111 and shake subassembly 4, first performance detection subassembly and the first subassembly 41 of collecting directly respectively, first performance detection subassembly sets up between directly shaking subassembly 4 and the first subassembly 41 of collecting. In this embodiment, first performance detection subassembly is used for detecting inductance coils's voltage current performance, and first performance detection subassembly includes brace table and a plurality of connection piece, is provided with the recess on the brace table, and a plurality of inductance coils that wait to detect place in the recess, and a plurality of connection piece settings are in the recess, and inductance coils one-to-one is connected with the connection piece, and the connection piece is connected with voltage current detection. Referring to fig. 7, the first collecting assembly 41 includes a plurality of first collecting grooves 411, a plurality of pushing blocks 412 and pushing block driving cylinders 413 which are arranged in parallel, the first driving assembly 32 drives the first manipulator assembly 31 to move between the first performance detecting assembly and the first collecting groove 41, and the first manipulator assembly 31 moves the inductance coil which is determined to be defective after the detection of the first performance detecting assembly from the supporting table into the first collecting groove 411. The number of the first collecting grooves 411 is the same as that of the pushing blocks 412, one pushing block 412 corresponds to one collecting groove 411, and the pushing block driving cylinder 413 simultaneously drives the plurality of pushing blocks 412 to move towards the first collecting grooves 411. If the induction coil is detected and judged to be qualified in the first performance detection assembly, the first manipulator assembly 31 moves the induction coil as qualified to the position of the material waiting position of the direct vibration assembly 4.
Referring to fig. 8, the straight vibration assembly 4 includes a straight vibration device 41, a straight vibration rail 42, and a stopper 43, the straight vibration rail 42 extending between the first conveyor assembly and the inspection turret assembly. The direct vibration rail 42 and the stop 43 are respectively arranged on the direct vibration device 41, the stop 43 is arranged in the extending direction of the direct vibration rail 42, the material level 44 is positioned in the direct vibration rail 42, and the stop 43 is arranged between the detection turret assembly 5 and the material level 44. The first manipulator assembly 31 places the inductor coils in the straight vibration track 42, the straight vibration device 41 continuously drives the inductor coils to move one by one to the material waiting position 44, and the stop block 43 stops the inductor coils in the material waiting position 44 from continuing to move forward, so that the inductor coils are prevented from falling off from the straight vibration track 42. The upper portion of the straight vibration rail 42 is provided with a baffle strip 45, the baffle strip 45 is in a long strip shape, and the length direction of the baffle strip 45 is parallel to the extending direction of the straight vibration rail 42. Along the extension direction of the straight vibration rail 42, a material waiting position 44 is arranged between the stop block 43 and the stop strip 45. The barrier strip 45 is provided with a plurality of air blowing pipes 46, and the air outlets of the air blowing pipes 46 face the straight vibration rail 42. The barrier strip 45 is arranged to prevent the inductor coils in the straight vibrating rail 42 from falling off the straight vibrating rail 42 during movement.
The inspection turret assembly 5 includes a turret assembly 51 and a plurality of inspection assemblies, and referring to fig. 9 and 10, the turret assembly 51 includes a first turntable 511, a plurality of second robot assemblies 512 and a first turntable driving assembly, a plurality of inspection positions are provided on the mounting end surface 111 of the mounting table 11, the plurality of inspection positions are provided along the circumferential direction of the first turntable 511, and one inspection assembly is located at each inspection position. A plurality of second robot assemblies 512 are arranged on the side wall of the first rotary table 511 facing the detection assemblies along the circumferential direction of the first rotary table 511, and the second robot assemblies 512 are used for driving the induction coils in the material waiting positions 44 to move to the positions of the detection assemblies.
The first turntable driving assembly comprises a plurality of supporting blocks 513, a rotation driving device 514 and a lifting driving assembly 515, wherein a second manipulator assembly 512 is correspondingly connected with one supporting block 513, and the rotation driving device 514 drives the first turntable 511 to rotate so as to drive the second manipulator assembly 512 on the first turntable 511 to move to each detection assembly.
The lifting driving assembly 515 comprises a plurality of springs 5151, a pushing block 5152 and a moving driving assembly, the springs 5151 are abutted between the first turntable 511 and the supporting blocks 513, the pushing blocks 5152 are respectively abutted to the supporting blocks 513, the moving driving assembly drives the pushing block 5152 to move, the pushing block 5152 is driven by the moving of the pushing block 5152 to drive the springs 5151 to compress, the springs 5151 are compressed to enable the distance between the second manipulator assembly 512 and the detection assembly to be increased, and the second manipulator assembly 512 can rotate after taking materials.
In this embodiment, the second robot assembly 512 includes a suction nozzle 5121 and a first vent pipe 5122, the suction nozzle 5121 is communicated with the first vent pipe 5122, the suction nozzle 5121 is disposed on the side wall of the support block 513 far away from the first rotary plate 611, the first vent pipe 5122 penetrates through the second rotary plate 511, the suction nozzle 5121 is connected with the first vent pipe 5122, the suction nozzle 5121 is located on the side of the first rotary plate 511 facing the detection assembly, the coil is fixed by the suction nozzle 5121, the requirement of the structure of the positioning assembly of the inductance coil in the detection position or the processing position can be reduced, and the coil can be transferred more quickly. The supporting block 513 is connected to the first ventilating pipe 5122, and the supporting block 513 is located between the suction nozzle 5121 and the first rotary plate 511. The spring 5151 is sleeved outside the first vent pipe 5122, and the spring 5151 abuts between the first rotary disc 511 and the supporting block 513. The first rotary disc 511 is provided with a plurality of rotation stopping components, one rotation stopping component is connected with a first ventilating pipe 5122, and the rotation stopping components are arranged on the side wall of the first rotary disc 511, which is far away from the suction nozzle 5121. The rotation stopping assembly comprises a rotation stopping block 5123 and a positioning pin 5124, the rotation stopping block 5123 is fixedly connected with a first ventilating pipe 5122, an open groove 5125 is formed in the rotation stopping block 5123, and the positioning pin 5124 is positioned in the open groove 5125, so that the rotation stopping block 5123 cannot rotate, and the rotation stopping block 5123 is fixedly connected with the first ventilating pipe 5122, so that the first ventilating pipe 5122 cannot rotate, and a coil can be accurately fixed by the suction nozzle 5121.
The turret assembly 51 includes a vent assembly 52, the vent assembly 52 being adapted to vent the first vent tube 5122 in each of the second robot assemblies 512. The vent assembly 52 includes a mounting bracket 521, a pneumatic slide ring 522, a plurality of second vent tubes 523, and a plurality of third vent tubes 524. The pneumatic slide ring 522 includes a stationary outer sleeve 5221 and a rotating body 5222, the rotating body 5222 being disposed within the stationary outer sleeve 5221, the rotating body 5222 being coupled to the first rotor disk 511, the rotating body 5222 rotating relative to the stationary outer sleeve 5221. The rotating body 5222 is connected to a plurality of second vent pipes 523, the outer wall of the stationary outer sleeve 5221 is connected to a plurality of third vent pipes 524, the second vent pipes 523 and the third vent pipes 524 are communicated in the pneumatic slip ring 522, and the second vent pipes 523 are connected to the first vent pipes 5122 in a one-to-one correspondence manner. The connection of the vent pipe is realized by the pneumatic slip ring 522 as the second robot assembly 512 is moved by the rotation of the turntable 511.
In the present embodiment, the mounting bracket 521 has an L-shape, and the mounting bracket 521 is disposed on the mounting end surface 111 of the mounting table 11. The mounting bracket 521 includes a vertical section 5211 and a horizontal section 5212, the vertical section 5211 is connected with the horizontal section 5212, the horizontal section 5212 is parallel with the mounting end surface 111, a first air outlet 5213 and a plurality of second air outlets 5214 are provided on the horizontal section 5212, the first air outlet 5213 is communicated with the plurality of second air outlets 5214, and the plurality of second air outlets 5214 are connected with the third air connecting pipe 524 in a one-to-one correspondence manner. When the pneumatic slip ring 522 is ventilated, the vacuum generator is connected to the first air outlet 5213, and the air pressure change of the second air outlets 5214 is simultaneously controlled through the first air outlet 5213, so that the adsorption states of the suction nozzles 5121 are simultaneously controlled, and the synchronism of the fixed inductance coils of the second manipulator assemblies 512 is realized.
Referring to fig. 10, the push block 5152 is shaped like a circular ring, the push block 5152 is parallel to the first rotary plate 511, the rotation driving device 514 is located in the inner circle of the circular ring, and the plurality of second robot assemblies 512 are arranged along the circumferential direction of the outer circle of the push block 5152. The inner circle of the circular pushing block 5152 provides a mounting position for the rotary driving device 5152, so that the layout of the turret assembly 51 is more reasonable.
The moving driving assembly comprises a mounting plate 5153, a moving plate 5154, four guide rods 5155, a fixed plate 5156, a rotating motor 5157, a threaded rod 5158, a transmission belt 5159 and rolling wheels 51510, wherein the mounting plate 5153, the moving plate 5154 and the fixed plate 5156 are respectively arranged in parallel, the rotating motor 5157 is arranged on the mounting plate 5153, the threaded rod 5158 simultaneously penetrates through the mounting plate 5153 and the moving plate 5154, the rolling wheels 51510 are sleeved outside the threaded rod 5158, the rolling wheels 51510 are connected with the rotating motor 5157 through the transmission belt 5159, the threaded part of the threaded rod 5158 is in threaded connection with the moving plate 5154, the moving plate 5154 is connected with a push block 5152 through the four guide rods 5155, and the four guide rods 5155 are arranged in parallel. The rotation driving device 514 is disposed on the fixed plate 5156, the fixed plate 5156 is disposed between the push block 5152 and the moving plate 5154, and the four guide rods 5155 respectively penetrate through the fixed plate 5156. The rotary motor 5157 drives the threaded rod 5158 to rotate through the transmission belt 5159, so as to drive the moving plate 5154 to move, and as the moving plate 5154 is connected with the push block 5152 through the guide rod 5155, the push block 5152 is moved, and the support block 513 is driven to compress the spring 5151, so that the distance between the suction nozzle 5121 and the detection assembly or the position to be detected is increased. When the rotary motor drives the threaded rod 5158 to move reversely through the transmission belt 5159 by the rotary motor 5157, the push block 5152 moves away from the first rotating disc 511, and the spring 5151 drives the supporting block 513 to move towards the detection component or the material waiting position, so that the suction nozzle 5121 can take materials conveniently. The guide rod 5155 guides the moving direction of the moving plate 5154, so that the moving direction of the push block 5152 is more precise, and the second robot assembly 512 is accurately pushed to move.
The suction nozzle 5121 is arranged on the side wall of the supporting block 513 far away from the spring 5151, the supporting block 513 is provided with a supporting rod 5131 and a rolling column 5132, the rolling column 5132 is cylindrical, the supporting rod 5131 penetrates through the rolling column 5132 along the axial direction of the rolling column 5132, and the rolling column 5132 is abutted to the push block 5152. When the first turntable 511 drives the plurality of second manipulator assemblies 512 to rotate, the rolling columns 5132 on the supporting blocks 513 abut against the push blocks 5152, and when the second manipulator assemblies 512 move, the rolling columns 5132 roll on the push blocks 5152, so that friction between the rolling columns 5132 and the push blocks 5152 can be reduced, and the second manipulator assemblies 512 can move more quickly.
When the rotary driving device drives the first rotary disc 511 to rotate, the second manipulator assembly 512 is driven to rotate, so that the second manipulator assembly 512 moves to a detection position arranged along the circumferential direction of the first rotary disc 511, when the second manipulator assembly 512 takes or discharges materials at the detection position, the movable driving assembly drives the push block 5152 to move, the support block 513 is driven to move, the spring 5151 compresses when the second manipulator assembly 512 moves to discharge materials, after discharging is completed, the movable driving assembly drives the push block 5152 to retreat away from the rotary disc 511, the spring 5151 drives the second manipulator assembly 512 to reset, so that the second manipulator assembly 512 can take materials conveniently, the plurality of detection positions can be arranged along the circumferential direction of the rotary disc 511, the overall layout of the device can be controlled more effectively while the detection comprehensiveness is improved, and therefore, the size of the device is controlled, and the plurality of second manipulator assemblies 512 are used for material transfer between the detection positions, the automation degree is improved, and the working efficiency is effectively improved.
The plurality of detecting components include a plurality of second performance detecting components 53, a plurality of correcting components 54 and a plurality of lateral CCD detecting components 55, the second performance detecting components 53 are used for performing electrical performance tests, the electrical performance tests may include resistance tests and the like, see fig. 11, the second performance detecting components 53 include a first testing frame 531 and a plurality of conductive blocks 532, a testing slot 5311 and a plurality of energizing slots 5312 are arranged on the first testing frame 531, the plurality of energizing slots 5312 are respectively communicated with the testing slot 5311, the conductive blocks 532 are located in the testing slot 5311, when the inductance coil is placed in the testing slot 5311, the conductive blocks 532 are abutted to pins on the inductance coil. The energizing groove 5312 is used for placing an energizing wire, and the energizing wire is connected with the conductive block 532.
Referring to fig. 12, the calibration assembly 54 includes a base 541 and a calibration jaw 542, the calibration jaw 542 is disposed on the base 541, and the calibration jaw 542 in this embodiment includes four jaw pieces.
Referring to fig. 13, the lateral CCD detecting assembly 55 includes a light-emitting source 551, a second test rack 552, and an image shaper 553, the second test rack 552 being disposed between the light-emitting source 551 and the image shaper 553. In this embodiment, the second test rack 552 is provided with a clamp block assembly, which includes two clamp blocks 554 and pneumatic clamp jaws 555, the pneumatic clamp jaws 555 driving the two clamp blocks 554 to move toward or away from each other, respectively. Two clamp blocks 554 of the clamp block assembly clamp the inductor coil when the inductor coil is placed on the second test rack 552.
From the material waiting position 44 as a starting point, along the circumferential direction of the first rotating disc 511, one correcting assembly 54, three second performance detecting assemblies 53, one correcting assembly 54, one lateral CCD detecting assembly 55, a rotary driving assembly, one correcting assembly 54 and one lateral CCD detecting assembly 55 are arranged in sequence, and the inductance coil can be corrected in the direction between detection, so that the situation that the detection precision is reduced due to the position deviation of the inductance coil is reduced. Second performance detection component 53 can be used to detect inductance coils's electrical property, CCD detection component can be used to detect inductance coils's outward appearance, operating personnel can be according to actual conditions, the quantity of adjustment correction component 54 and side direction CCD detection component 55, and correction component 54 and side direction CCD detection component 55 cross arrangement, can fix a position between the outward appearance that carries out side direction CCD detection component 55 each time detects, in order to guarantee that each outward appearance detects all to correspond inductance coils's different sides, in order to guarantee inductance coils's comprehensive nature that detects. Every side direction CCD determine module 55 corresponds the different side of detection inductance coils, can be provided with a rotary drive subassembly at two side direction CCD determine module 55 and change inductance coils's direction, rotary drive subassembly is including rotatory piece, rotary drive device and fixing base, rotary drive device sets up on the fixing base, the rotatory piece of rotary drive device drive rotates, be provided with the constant head tank on the lateral wall of rotatory piece orientation second manipulator subassembly 512, inductance coils places in the constant head tank, the constant head tank is provided with the opening towards second manipulator subassembly 512, second manipulator subassembly 512 gets through the opening and puts inductance coils.
Referring to fig. 14, the transferring assembly 6 includes a second turntable 61 and a second turntable driving device, the second turntable driving device drives the second turntable 61 to rotate, the second turntable driving device is a rotating motor, a plurality of positioning slots 62 are formed in the second turntable 61 along the circumferential direction of the second turntable, the first turntable 511 drives the second manipulator assembly 512 to move to the positioning slots 62, and the second manipulator assembly 512 places the inductor coils in the positioning slots 62 or takes the inductor coils in the positioning slots 62 away.
The second conveying assembly 7 includes a third robot assembly 71 and a third robot movement driving assembly 72, the third robot movement driving assembly 72 drives the third robot assembly 71 to move between the transfer assembly 6 and the defective product sorting assembly 8, and the third robot assembly 71 is configured to move the inductor coil, which is a defective product, on the transfer assembly 6 to the defective product sorting assembly 8. In the present embodiment, the third robot assembly 71 includes a second mounting seat 711, a suction nozzle 712, and a rotation stop assembly, and the suction nozzle 712 and the rotation stop assembly are respectively disposed on the second mounting seat 711. The rotation stopping assembly comprises a rotation stopping block 713 and a positioning pin 714, an opening groove 715 is formed in the rotation stopping block 713, the positioning pin 714 is located in the opening groove 715, and the suction nozzle 712 is fixedly connected with the rotation stopping block 713. When the third robot assembly 71 moves between the second turntable 61 and the defective product sorting assembly 8 to transfer the inductor, the inductor is fixed by the suction nozzle 712, and the suction nozzle 712 fixes the inductor by suction force. The suction nozzle 712 is fixedly connected with the rotation stopping block 713, and the positioning pin 714 is located in the opening groove 715 of the rotation stopping block 713, so that the rotation stopping block 713 cannot rotate, the suction nozzle 712 cannot rotate all the time during the process of transferring the inductance coil, and the inductance coil is prevented from falling from the suction nozzle 712. The third robot movement driving assembly 72 drives the third robot assembly 71 to extend in the horizontal direction and the vertical direction through a connection structure of two sets of rotary motors and a screw.
The positioning groove 62 on the second rotating disc 61 is provided with a first opening 621, a second opening 622 and a third opening 623, the first opening 621, the second opening 622 and the third opening 623 are respectively communicated with the positioning groove 62, the first opening 621 is arranged on one side of the positioning groove 62 facing the suction nozzle 712, the second opening 622 and the third opening 623 are oppositely arranged, and the first opening 621 is arranged between the second opening 622 and the third opening 623. The inductance coil is fixed on the suction nozzle 712, the first opening 621 is arranged towards the suction nozzle 712, the suction nozzle 712 passes through the first opening 621 to take away the inductance coil, the operation is convenient and fast, and the pins on the inductance coil correspondingly penetrate through the second opening 622 and the third opening 623, so that the pins on the inductance coil are prevented from being extruded and deformed in the positioning groove 62.
Referring to fig. 15, the defective classification assembly 8 includes a push block assembly 81 and a classification tray 82, a plurality of classification grooves 821 are provided on the classification tray 82, and the classification grooves 821 are arranged in parallel. The push block assembly 81 comprises a fixed seat 811, a first installation seat 812, a push block 813, a pushing device 814 and a push block moving assembly 83, wherein the push block 813 and the pushing device 814 are arranged on the first installation seat 812, the pushing device 814 is an air cylinder, the push block moving assembly 83 drives the first installation seat 812 to move along the arrangement direction of the plurality of classification grooves 821, and the first installation seat 812 and the push block moving assembly 83 are arranged on the fixed seat 811.
Referring to fig. 16, a push level 815 is disposed on the first mount 812, and in this embodiment, the push level 815 is located within a recess 8121 disposed on top of the first mount 812. The pushing position 815 is arranged between the pushing block 813 and the sorting tray 82, and the pushing device 814 drives the pushing block 813 to move toward the sorting groove 821 along the extending direction of the sorting groove 821. In this embodiment, a positioning step 816 is disposed on one end of the pushing block 813 facing the pushing position 815, the positioning step 816 is formed with a positioning recess 817 and a positioning block 818 protruding relative to the positioning recess 817, the positioning recess is adjacent to the pushing position 815, and the positioning block 818 is located above the positioning recess 817 in the vertical direction.
The second mounting seat 812 is provided with a first limiting plate 8122 and a second limiting plate 8123, and the first limiting plate 8122 and the second limiting plate 8123 are arranged in the groove 8121. The pushing block 813 moves in a limiting groove 8124 between the first limiting plate 8122 and the second limiting plate 8123, and the pushing block 813 is located outside the limiting groove 8124. Because the ejector pad 813 is located in the limiting groove 8124 between the first limiting plate 8122 and the second limiting plate 8123, the first limiting plate 8122 and the second limiting plate 8123 guide the moving direction of the ejector pad 813, and the accuracy of the ejector pad 813 pushing the inductance coil is improved.
Each classification groove 821 is provided with a side plate 822 on each side along the extending direction of the classification groove 821, and the arrangement of the side plates 822 partitions the two adjacent classification grooves 821 to prevent the induction coils in the two adjacent classification grooves 821 from colliding with each other. Two positioning bars 823 are arranged in each classification groove 821, the two positioning bars 823 are parallel, and the positioning bars 823 extend along the extension direction of the classification groove 821. The protruding height of the side plate 822 is higher than that of the positioning bar 823 based on the bottom surface of the sorting groove 821. When the inductor is slid into the sorting groove 821, the positioning bars 823 support the stitches on the inductor, so that the bobbin portions of the inductor are positioned in the two positioning bars 823, and the inductor keeps moving in the sorting groove 821.
The sorting groove 821 comprises a feeding port 824 and a baffle 825, the feeding port 824 is arranged between the pushing block 813 and the baffle 825, the side plate 822 is arranged between the feeding port 824 and the baffle 825, an avoiding groove 826 is arranged between the side plate 822 and the baffle 825, the avoiding groove 826 is communicated with the sorting groove 821, and the avoiding grooves 826 of the adjacent sorting grooves 821 are communicated with each other. An inductor 827 is arranged on the sorting tray 82, a sensing end of the inductor 827 is arranged opposite to the avoiding groove 826, and the sensing end of the inductor 827 can detect whether each sorting groove 821 is filled with an induction coil or not through the avoiding groove 826.
In this embodiment, the pushing block moving assembly 83 includes a rotating motor 831, a transmission belt 832 and a screw rod 833, the rotating motor 831 drives the screw rod 833 to rotate through the transmission belt 832, the screw rod 833 is connected to the first mounting seat 812, and the rotation of the screw rod 833 drives the first mounting seat 812 to move along the arrangement direction of the plurality of sorting grooves 821. A guide rail 8111 is arranged on the side wall of the fixed seat 811 facing the first installation seat 812, the extending direction of the guide rail 8111 is parallel to the axial direction of the screw rod 833, the first installation seat 812 is connected with the guide rail 8111 in a matching manner, and the guide rail 8111 guides the moving direction of the first installation seat 812.
The control system in the inductance coil detecting and packaging device classifies the classification slots 821 on the classification plate 82 corresponding to different detection items of the inductance coil, for example, the inductance coil with unqualified electrical property detection is concentrated in the first classification slot 821, and the inductance coil with unqualified appearance detection is concentrated in the second classification slot 821. When the inductance coils are discharged, the detected inductance coils are placed in the positioning grooves 62 on the rotary table 61 one by one, the control system controls the rotary table to rotate according to the detection result, the inductance coils on the second rotary table 61 are driven to move to the qualified product discharging position and the defective product discharging position, when an inductance coil on the second rotary table 61 moves to a defective product blanking position, the second conveying assembly 7 conveys the inductance to the material pushing position 815 on the pushing block 813, the control system drives the first mounting seat 812 to move to the corresponding classification groove 821 according to the detection result, the pushing device 814 drives the pushing block 813 to move towards the classification groove 821, the inductance coil in the material pushing position 815 is pushed into the classification groove 821, a plurality of defective products are classified, waste of resources caused by unified treatment after the defective products of different types are stacked together is avoided, and the defective products of different types of operators can be conveniently analyzed. Through second carousel 61 drive inductance coils to passing article unloading department and defective products unloading, can carry out the unloading of passing article and defective products simultaneously for rationally carrying out the overall arrangement to blanking structure better, effectively improve work efficiency.
The inductance coil detecting and packaging device comprises a fixing frame 84, wherein the fixing frame 84 is arranged on a mounting end surface 111 of the mounting table 11, and the second conveying assembly 7 and the third conveying assembly 9 are respectively arranged on different side walls of the fixing frame 84.
The third conveyor assembly 9 is used to drive the inductor coils on the second turntable 61 onto the baling assembly 10. The baling assembly 10 is used to bale an induction coil as a pass.
In this embodiment, the passing product blanking position of the second turntable 61 is close to the third conveying assembly 9, and the defective product blanking position is close to the second conveying assembly. Inductance coil detects packing plant is including marking vision subassembly 18, mark vision subassembly 18 and be located between second carousel 61 and the packing subassembly 10, mark vision subassembly 18 and be used for marking the inductance coil as passing article, passing article unloading department on the second carousel 61 can be located and mark vision subassembly 18 and packing subassembly 10 before, mark vision subassembly 18 and accomplish the packing back to passing article inductance coil on the second carousel 61, second carousel 61 drive and passing article remove to passing article unloading department, third conveying assembly 9 transmits passing article to packing subassembly 10. Referring to fig. 17, the marking visual assembly 18 includes a mounting frame 181, a marking machine 182, a light source 183, and a dust suction pipe 184, wherein the marking machine 182 is disposed on the mounting frame 181, the second turntable 61 is located between the marking machine 182 and the light source 183, the dust suction pipe 184 is located below the second turntable 61, a dust suction opening of the dust suction pipe 184 faces the second turntable 61, and the dust suction pipe 184 is used for sucking dust generated by marking.
Referring to fig. 18, the third conveyor assembly 9 includes a fourth robot assembly 91 and a fourth robot movement drive assembly 92, the fourth robot movement drive assembly 92 driving the fourth robot assembly 91 to move between the second turntable 61 and the baling assembly 10. The fourth manipulator movement driving assembly 92 comprises a mounting frame 921, a rotation driving device 922, a rotating block 93 and a moving block 923, wherein the mounting frame 921 is fixed on the mounting frame 84, and the rotation driving device 922 is a rotating motor. The driving rod of the rotary driving device 922 runs through the mounting frame 921 to be connected with the rotating block 93, and the mounting frame 921 deviates from the side wall of the rotary driving device 922 and is provided with a sliding groove 924 in an arc shape. Referring to fig. 19 and 20, the rotating block 93 includes a protrusion column 930, a first block 931, a second block 932, and a spring 933, the protrusion column 930 is disposed on a side wall of the first block 931 facing the chute 924, the protrusion column is located within the chute 924 and moves within the chute 924. First concatenation piece 931 is provided with first annular groove 934 towards the lateral wall of second concatenation piece 932 on, and second concatenation piece 932 is provided with second annular groove 935 towards the lateral wall of first concatenation piece 931 on, first annular groove 934 and second annular groove 935 intercommunication, and the both ends of spring 933 along spring 933 elasticity direction are located first annular groove 934 and second annular groove 935 respectively. The protrusion column 930 is located on the wall of the first block 931 facing the sliding slot 924, and the driving rod of the rotary driving device 922 of the rotary block 93 is connected to the second block 932. The rotating block 93 is connected with the moving block 923, and the fourth robot assembly 91 is disposed on the moving block 923. The rotation driving device 922 drives the rotating block 93 to move along the extending direction of the sliding groove 924, and in the moving process of the rotating block 93, the spring 933 compresses along with the movement of the first splicing block 931 in the sliding groove 924, so that the rotating block 93 can slide in the sliding groove 924. The removal of turning block 93 drives movable block 923 and removes to drive the fourth manipulator assembly 91 on the movable block 923 and remove, realize the transmission of fourth manipulator assembly 91 at the material between second carousel 61 and the subassembly 10 of packing, the setting of spout 924 can lead the direction of fourth manipulator assembly 91, makes fourth manipulator assembly 91 snatch inductance coils more accurately.
In the present embodiment, the fourth robot assembly 91 includes a mounting seat 911, a suction nozzle 912 and a rotation stop assembly, and the suction nozzle 912 and the rotation stop assembly are respectively disposed on the mounting seat 911. The rotation stopping assembly comprises a rotation stopping block 913 and a positioning pin 914, the suction nozzle 912 is fixedly connected with the rotation stopping block 913, an opening groove 915 is formed in the rotation stopping block 913, and the positioning pin 914 is located in the opening groove 915. Because the positioning pin 914 is located in the opening groove 915 of the rotation stop block 913, the rotation stop block 913 cannot rotate, so that the suction nozzle 912 cannot rotate all the time during transferring the inductance coil, and the inductance coil is prevented from falling from the suction nozzle 912.
Be provided with guide rail 925 on the mounting bracket 921 the lateral wall towards removal piece 923, guide rail 925 extends along the horizontal direction between second carousel 61 and packing subassembly 10, and guide rail 925 and spout 924 are located the same one side of mounting bracket 921, and removal piece 923 is connected with the guide rail 925 cooperation. The guide rail 925 guides the moving direction of the moving block 923, so that the fourth manipulator assembly 91 can grasp the inductor coil more accurately.
Referring to fig. 21, the packing assembly 10 includes a fixing frame 101, a packing rail 102, a rail driving assembly 103, a CCD detecting assembly 104, a carrier tape hot-pressing assembly 105, and a carrier tape press-feeding assembly 106, the packing rail 102 and the rail driving assembly 103 are disposed on the fixing frame 101, the rail driving assembly 103 is used for driving the material on the packing rail 102 to move, and the carrier tape hot-pressing assembly 105 is disposed between the CCD detecting assembly 104 and the carrier tape press-feeding assembly 106 along the extending direction of the packing rail 102. In this embodiment, the rail driving assembly 103 comprises a plurality of rolling rollers 1031, a driving motor 1032 and a transmission belt, and the driving motor 1032 drives one rolling roller 1031 to rotate through the transmission belt, so as to drive the other rolling rollers 1031 to rotate, and drive the packaging tape located in the packaging rail 102 to move. The fixing frame 101 is provided with a first supporting rod 1011, a second supporting rod 1012 and a third supporting rod 1013, the first supporting rod 1011 is arranged below the mounting end surface 111 of the mounting table 11 in the vertical direction, the packing rail 102 is arranged between the first supporting rod 1011 and the second supporting rod 1012, the third supporting rod 1013 can be located in the extending direction of the packing rail 102, and the third supporting rod 1013 can be located at the downstream of the hot-press assembly 105. In the horizontal direction, the CCD detection assembly 104 is disposed between the first support rod 1011 and the second support rod 1012, and the second support rod 1013 is disposed between the CCD detection assembly 104 and the carrier tape thermocompression assembly 105. The first support rod 1011, the second support rod 1012 and the third support rod 1013 are respectively connected with a rotation driving device 1014, or only the third support rod 1013 is connected with the rotation driving device 1014. The first support rod 1011 is used for winding and unwinding a packaging tape for placing an inductance coil, the second support rod 1012 is used for winding and unwinding a sealing tape, and the third support rod 1013 is used for winding and unwinding a packaging tape for completing hot pressing.
Referring to fig. 22, the carrier tape hot-pressing assembly 105 includes two pressing blocks 1051, a pneumatic clamping jaw 1052, a moving frame 1053, a mounting frame 1054 and a pressing block driving device 1055, the pneumatic clamping jaw 1052 drives the two pressing blocks 1051 to move toward or away from each other, the two pressing blocks 1051 and the pneumatic clamping jaw 1052 are disposed on the moving frame 1053, the pressing block driving device 1055 is disposed on the mounting frame 1054, and the pressing block driving device 1055 drives the moving frame 1053 to move toward the packing rail 102, so as to drive the two pressing blocks 1051 to move simultaneously. The side wall of the mounting frame 1054 facing the moving frame 1053 is provided with a guide rail 1056 extending along the vertical direction, the moving frame 1053 is connected with the guide rail 1056 in a matching way, and the moving frame 1053 moves along the extending direction of the guide rail 1056.
In this embodiment, one pressing block 1051 is correspondingly connected to one moving block 1057, and the pneumatic clamping jaw 1052 drives the two moving blocks 1057 to move towards or away from each other, so as to drive the two pressing blocks 1051 to move. A spring 1058 is connected between the moving block 1057 and the pressing block 1051. The two pressing blocks 1051 are respectively connected with a heating pipe 1059, the heating pipes 1059 enable the temperature of the pressing blocks 1051 to rise, the sealing adhesive tape is bonded on the packaging tape, and in the pressing process of the pressing blocks 1051, the springs 1059 buffer the driving force of the pressing block driving device 1055, so that the pressing effect is better.
The CCD detection assembly 104 includes a detection mount 1041 and an image former 1042, the image former 1042 being disposed on the detection mount 1041. The image former 1042 is arranged above the packaging track 102, along the driving direction of the track driving component 103, the CCD detecting component 104 is located at the upstream of the carrier tape hot-pressing component 105, the CCD detecting component 104 is used for detecting whether the inductor coil as a passing product is placed in the placing lattice on the packaging tape, so as to avoid the leakage, and the hot-pressing adhesion of the sealing cost can be performed after the detection is finished.
Referring to fig. 23, the carrier tape press-fit belt feeding assembly 106 includes a pressing roller 1061, a fixing frame 1062, and a pressing roller driving assembly, where the pressing roller driving assembly includes a cylinder 1063, a moving frame 1064, and a spring 1065, the cylinder 1063 is disposed on the fixing frame 1062, a guide 1065 is disposed on a side wall of the fixing frame 1062 facing the moving frame 1064 in a vertical direction, the moving frame 1064 is connected with the guide 1065 in a matching manner, and the pressing roller 1061 is disposed on the moving frame 1064. The air cylinder 1063 drives the movable frame 1064 to move along the moving direction of the guide rail 1065, so as to drive the pressing roller 1061 to move towards the baling track 102; the carrier tape press assembly 104 is located upstream of the carrier tape press assembly 106 in the driving direction of the track drive assembly. After the hot pressing of the sealing tape is completed by the carrier tape hot pressing assembly 104, the sealing tape moves in the packaging rail 102 to drive the pressing roller 1061 to roll, and the pressing roller 1061 flattens the sealing tape, so that the wrapping paper can be conveniently rolled.
The third conveying assembly 9 moves the induction coils on the second rotating disc 61 and at the blank position of the qualified product to the packaging belt on the packaging track 102, and the packaging belt is provided with placing grids. The track driving assembly 103 drives the packaging belt to move, and when the packaging belt moves, the third conveying assembly 9 places the inductance coils on the second rotating disc 61 into the placing grids of the packaging belt one by one, and one placing grid corresponds to one inductance coil, so that the mutual collision of the inductance coils is avoided, and the damage is caused. The packaging belt gradually passes through the CCD detection assembly 104, and the CCD detection assembly 104 detects whether the induction coil is placed on the placing grids on the packaging belt or not. An operator covers the packaging tape with the sealing tape, when the packaging tape passes through the carrier tape hot pressing assembly 105, the pressing block driving device 1055 drives the pressing block 1051 to move towards the packaging track 102, the heating pipe 1059 heats the pressing block 1051, the sealing tape is adhered to the packaging tape by the high-temperature pressing block 1051, the pressing roller in the carrier tape pressing and conveying belt assembly 106 located downstream of the carrier tape hot pressing assembly 104 flattens the sealing fee, and the packaging paper roll is placed on the third supporting rod 1013.
The feeding assembly 1 feeds a plurality of inductance coils simultaneously through the jig 12, the first manipulator assembly 31 moves the inductance coils from the feeding assembly 1 to the position of a material waiting position 44, the first turntable driving assembly drives the first turntable 511 to rotate, a plurality of second manipulator assemblies 513 on the first turntables 511 take the material to the position of the material waiting position 44 one by one, the second manipulator assemblies 513 detect the inductance coils to the positions of a plurality of detection assemblies one by one to ensure the comprehensiveness of the detection of the inductance coils, after one inductance coil is detected, the second manipulator assemblies 513 drive the inductance coils to move to the positioning grooves 611 on the second turntables 61, the second turntables 61 drive the inductance coils to rotate to enable the inductance coils to move to the position of a defective product blanking position and the position of a packaging assembly, the second conveying assembly 7 moves the inductance coils to the position of a defective product classification assembly, the third conveying assembly 9 moves the inductance coils to the position of packaging paper on the packaging track 102, packing paper in the packing track 102 moves, inductance coils are placed in the placing grids of the packing paper one by one correspondingly, meanwhile, a pressing block 1051 compresses the sealing adhesive tape on the packing paper, in the process, a plurality of detection assemblies are arranged along the circumferential direction of the first rotary table 511, the part layout of the device is more reasonable, the size of the device is effectively controlled, a plurality of second mechanical arm assemblies 513 on the first rotary table 511 can all take the material to transfer coils to the detection assemblies, each detection assembly can simultaneously detect the inductance coils, the efficiency is effectively improved, the coils which are detected are completed through the second rotary table 61 to the defective product classification assembly and the packing assembly, the blanking of defective products and qualified products is better carried out, the quality of the delivered products is guaranteed, and meanwhile, the working efficiency is further improved.
Finally, it should be emphasized that the above-described preferred embodiments of the present invention are merely examples of implementations, rather than limitations, and that many variations and modifications of the utility model are possible to those skilled in the art, without departing from the spirit and scope of the utility model.

Claims (8)

1. Defective products unloading subassembly, its characterized in that includes: the transfer component comprises a rotary table and a rotary table driving device, the rotary table driving device drives the rotary table to rotate, and a plurality of positioning grooves are formed in the rotary table in the circumferential direction of the rotary table;
the conveying assembly comprises a manipulator assembly and a manipulator movement driving assembly, and the manipulator movement driving assembly drives the manipulator assembly to move between the transfer assembly and the defective product classification assembly;
the classified component of defective products includes ejector pad subassembly and categorised dish, be provided with a plurality of categorised grooves on the categorised dish, it is a plurality of categorised groove parallel arrangement, the ejector pad subassembly includes first mount pad, ejector pad, push device and ejector pad removal subassembly, the ejector pad with push device sets up on the first mount pad, the ejector pad removes the subassembly drive first mount pad is along a plurality of the range direction of categorised groove removes, be provided with on the first mount pad and push the material level, it sets up to push away the material level the ejector pad with between the categorised dish, the push device drive the ejector pad is followed the extending direction orientation of categorised groove the categorised groove removes.
2. The defective blanking assembly of claim 1, wherein:
the manipulator subassembly includes second mount pad, suction nozzle and the subassembly that splines, the suction nozzle with the subassembly that splines sets up respectively on the second mount pad, the subassembly that splines is including the piece and the locating pin that splines, it is provided with the open slot on the piece to spline, the locating pin is located in the open slot, the suction nozzle with the piece fixed connection that splines.
3. The defective blanking assembly of claim 2, wherein:
the positioning groove is provided with a first opening, a second opening and a third opening, the first opening, the second opening and the third opening are communicated with the positioning groove respectively, the first opening is arranged on one side, facing the suction nozzle, of the positioning groove, the second opening and the third opening are arranged oppositely, and the first opening is located between the second opening and the third opening.
4. The defective blanking assembly of claim 1, wherein:
the material pushing device is characterized in that one end, facing the material pushing position, of the pushing block is provided with a positioning step, a positioning block and a positioning concave portion are formed on the positioning step, the positioning concave portion is adjacent to the material pushing position, and the positioning block is located above the positioning concave portion in the vertical direction.
5. The defective blanking assembly of claim 1, wherein:
the first mounting seat is provided with a first limiting plate and a second limiting plate, the push block moves in a limiting groove between the first limiting plate and the second limiting plate, and the push block is located outside the limiting groove.
6. The defective blanking assembly of any one of claims 1 to 5, wherein:
every categorised groove is followed the extending direction's of categorised groove both sides are provided with the curb plate respectively, two be provided with two location strips, two between the curb plate location strip parallel arrangement, the location strip is followed the extending direction of categorised groove extends, based on the bottom surface of categorised groove, the protruding height of curb plate is higher than the protruding height of location strip.
7. The defective blanking assembly of claim 6, wherein:
the classification groove comprises a feeding opening and a baffle, the feeding opening is arranged between the pushing block assembly and the baffle, a plurality of side plates are arranged between the feeding opening and the baffle, an avoiding groove is arranged between the side plates and the baffle, and the avoiding groove is communicated with the classification groove;
an inductor is arranged on the classification disc, and an induction end of the inductor is opposite to the avoiding groove.
8. Inductance coil detects packing plant, its characterized in that: comprising a rejects blanking assembly as set forth in any one of claims 1 to 7.
CN202120648988.8U 2021-03-30 2021-03-30 Defective product blanking assembly and inductance coil detection packaging device Active CN215827110U (en)

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Application Number Priority Date Filing Date Title
CN202120648988.8U CN215827110U (en) 2021-03-30 2021-03-30 Defective product blanking assembly and inductance coil detection packaging device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202120648988.8U CN215827110U (en) 2021-03-30 2021-03-30 Defective product blanking assembly and inductance coil detection packaging device

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114932101A (en) * 2022-07-25 2022-08-23 苏州朗坤自动化设备股份有限公司 Hall component sorting equipment

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114932101A (en) * 2022-07-25 2022-08-23 苏州朗坤自动化设备股份有限公司 Hall component sorting equipment

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