CN214816373U - Magnet pay-off assembly quality - Google Patents

Abstract

The utility model discloses a magnet pay-off assembly quality, including a magnet feed mechanism, set up in magnet feed mechanism side below and be located a magnet blanking mechanism of material area conveying base plate top, and set up a magnet assembly devices on material area conveying base plate, this magnet assembly devices is including locating an assembly positioning seat of material area conveying base plate top, locate a front and back push cylinder on the material area conveying base plate side, connect the output of front and back push cylinder and a magnet conveying board that the activity inserted in the assembly positioning seat, and locate the magnet assembly push-down subassembly of assembly positioning seat top. The utility model provides a magnet pay-off assembly quality can accomplish magnet pay-off and magnet assembly operation automatically, realizes integrating each mechanism on same platform equipment, and the action is accurate, and degree of automation is high, improves whole pay-off and assembly efficiency, can improve the degree of accuracy of magnet assembly moreover, does benefit to improvement work efficiency and product quality.

Description

Magnet pay-off assembly quality

Technical Field

The utility model relates to an automation equipment field especially relates to a magnet pay-off assembly quality.

Background

The heating base is an important part in the electronic cigarette, and a magnet needs to be assembled on the heating base. The traditional mode that adopts manual assembly, not only assembly efficiency is low, and the assembly degree of accuracy is low moreover. Therefore, automatic assembly equipment appears on the market, however, the automatic assembly equipment on the market at present cannot integrate mechanisms such as magnet feeding and magnet assembly on the same equipment, and manual intervention is needed among all operation procedures, so that the processing and assembly efficiency is influenced.

SUMMERY OF THE UTILITY MODEL

To the above, not enough, the utility model aims to provide a magnet pay-off assembly quality can accomplish magnet pay-off and magnet assembly operation automatically, realizes integrating each mechanism on same platform equipment, and the action is accurate, and degree of automation is high, improves whole pay-off and assembly efficiency, can improve the degree of accuracy of magnet assembly moreover, does benefit to improvement work efficiency and product quality.

The utility model discloses a reach the technical scheme that above-mentioned purpose adopted and be:

a magnet feeding and assembling device is characterized by comprising a magnet feeding mechanism, a magnet blanking mechanism arranged below the side of the magnet feeding mechanism and positioned above a material belt conveying substrate, and a magnet assembling mechanism arranged on the material belt conveying substrate, wherein the magnet assembling mechanism comprises an assembling positioning seat arranged above the material belt conveying substrate, a front and back pushing cylinder arranged on the side edge of the material belt conveying substrate, a magnet conveying plate connected to the output end of the front and back pushing cylinder and movably inserted into the assembling positioning seat, and a magnet assembling pressing component arranged above the assembling positioning seat; a magnet carrier is arranged on the magnet conveying plate, two second material passing holes are respectively formed in the assembling and positioning seat and the magnet carrier, and at least one positioning through hole is respectively formed in the assembling and positioning seat and the magnet conveying plate; the magnet assembly pressing component comprises a longitudinal installation base block arranged on the assembly positioning seat, a pressing cylinder arranged on the longitudinal installation base block, a pressing positioning base connected to the output end of the pressing cylinder, at least one positioning insertion column arranged on the pressing positioning base and facing the positioning through hole, and two magnet pressing columns arranged on the pressing positioning base and facing the second material passing hole.

As a further improvement, the assembly positioning seat is provided with a pressing positioning block, and two at least guiding insertion holes for inserting the two magnet pressing columns are arranged on the pressing positioning block.

As a further improvement, the magnet feeding mechanism includes a chassis, sets up feed cylinder on a magnet on the chassis and sets up in chassis below middle part and connect in a rotary drive subassembly of feed cylinder on magnet, wherein, is formed with a plurality of vertical magnet slots on this magnet feed cylinder.

As a further improvement, the rotation driving assembly includes a rotation driving servo motor, connects in a speed reducer of rotation driving servo motor's output and connects the output of speed reducer and magnet charging barrel in an integrative one exempt from key bush.

As a further improvement of the utility model, the magnet blanking mechanism comprises a magnet blanking control component arranged on one side of the chassis, a magnet blanking component arranged below the magnet blanking control component, and a blanking in-place detection component arranged below the magnet blanking component, wherein the magnet blanking control component comprises a connecting block inserted on the side edge of the chassis, a blanking control block movably connected with the connecting block, and a blanking control cylinder connected with the blanking control block, the blanking control block is mainly formed by connecting a blanking stop block and a blanking passing block, two upper blanking holes matched with the longitudinal magnet slots are formed on the blanking passing block, two blanking holes corresponding to the upper blanking holes are formed on the connecting block, and a side slot for the movable insertion of the blanking stop block is formed on the connecting block; the magnet blanking assembly comprises two blanking through rods which are longitudinally arranged below the connecting block and correspondingly communicated with the two blanking holes, a magnet detection optical fiber arranged on the periphery of the upper part of the blanking through rod, a blanking positioning seat arranged on the lower part of the blanking through rod and through which the blanking through rod passes, and a positioning connecting rod connected between the connecting block and the blanking positioning seat; the blanking in-place detection assembly comprises an in-place detection upper base block arranged at the lower end of a blanking positioning seat, a detection base arranged below the in-place detection upper base block, an in-place detection lower base block arranged on the detection base, and two groups of correlation detection optical fibers arranged on the detection base and penetrating to the upper end of the in-place detection lower base block, wherein two first material passing holes corresponding to blanking through rods are formed in the in-place detection upper base block, and two heteropolar magnets are arranged below the two first material passing holes in the in-place detection lower base block.

As a further improvement, a movable cavity for the movable insertion of the magnet conveying plate is formed in the assembly positioning seat, the blanking in-place detection assembly is arranged on the assembly positioning seat, and the movable cavity is positioned between the upper base block and the lower base block in the in-place detection

As a further improvement of the utility model, the heating device further comprises a heating seat positioning mechanism arranged below the material belt conveying substrate, wherein the heating seat positioning mechanism comprises a positioning pushing cylinder, a positioning pushing rod connected with the output end of the positioning pushing cylinder and a longitudinal positioning structure arranged above the positioning pushing rod, a step is formed on the positioning pushing rod, and an arc-shaped guide surface is formed on the side surface of the step; the longitudinal positioning structure comprises a longitudinal positioning rod arranged on the positioning push rod and a pulley which is connected with the longitudinal positioning rod and is arranged on the positioning push rod in a sliding manner, the upper end of the longitudinal positioning rod is embedded into the assembly positioning seat, and the upper end of the longitudinal positioning rod is provided with a heating seat positioning groove.

The utility model has the advantages that: by magnet feed mechanism, magnet blanking mechanism, magnet assembly devices who has special structural design and the seat positioning mechanism that generates heat combine together, can accomplish magnet pay-off and magnet assembly operation automatically, realize integrating each mechanism on same platform equipment, the action is accurate, and degree of automation is high, improves whole pay-off and assembly efficiency, can improve the degree of accuracy of magnet assembly moreover, does benefit to improvement work efficiency and product quality.

The above is an overview of the technical solution of the present invention, and the present invention is further explained with reference to the accompanying drawings and the detailed description.

Drawings

Fig. 1 is a schematic view of the overall structure of the magnet feeding and assembling device of the present invention;

fig. 2 is a schematic view of a part of the structure of the magnet feeding and assembling device of the present invention;

FIG. 3 is a schematic view of the structure of the present invention in which the magnet blanking control assembly is combined with the chassis;

fig. 4 is a schematic structural view of the magnet blanking mechanism of the present invention;

fig. 5 is a schematic view of a part of the structure of the magnet assembling mechanism and the magnet blanking mechanism of the present invention;

fig. 6 is a schematic structural view of a positioning mechanism of a heating seat of the present invention;

fig. 7 is another schematic structural view of the positioning mechanism of the heating seat of the present invention;

FIG. 8 is a schematic view of a portion of the material belt with several heating seats of the present invention;

fig. 9 is a schematic view of the overall structure of the middle material belt conveying device of the present invention;

fig. 10 is a schematic view of a part of the structure of the middle material belt conveying device of the present invention.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the intended purpose, the following detailed description of the embodiments of the present invention is provided in conjunction with the accompanying drawings and preferred embodiments.

Referring to fig. 1, an embodiment of the present invention provides a magnet feeding and assembling apparatus 3, which includes a magnet feeding mechanism 31, a magnet blanking mechanism 32 disposed below the magnet feeding mechanism 31 and above the material belt conveying substrate 11, and a magnet assembling mechanism 33 disposed on the material belt conveying substrate 11.

Specifically, as shown in fig. 2 and 3, the magnet feeding mechanism 31 includes a chassis 311, an upper magnet barrel 312 disposed on the chassis 311, and a rotary driving assembly 313 disposed at the middle portion below the chassis 311 and connected to the upper magnet barrel 312, a plurality of longitudinal magnet slots 3121 are formed on the upper magnet barrel 312, the rotary driving assembly 313 includes a rotary driving servo motor 3131, a speed reducer 3132 connected to an output end of the rotary driving servo motor 3131, and a keyless shaft bush 3133 connecting an output end of the speed reducer 3132 and the upper magnet barrel 312 into a whole, and the rotary driving assembly 313 can drive the upper magnet barrel 312 to rotate on the chassis 311. When the upper magnet barrel 312 rotates, the longitudinal magnet slots 3121 on the upper magnet barrel 312 sequentially rotate to correspond to the magnet blanking mechanism 32, so that the magnets in the upper magnet barrel 312 can accurately fall into the magnet blanking mechanism 32.

Specifically, as shown in fig. 3 to 5, the magnet blanking mechanism 32 includes a magnet blanking control component 321 disposed on one side of the chassis 311, a magnet blanking component 322 disposed below the magnet blanking control component 321, and a blanking-in-place detection component 323 disposed below the magnet blanking component 322, wherein, the magnet blanking control component 321 comprises a connecting block 3211 inserted on the side of the bottom plate 311, a blanking control block 3212 movably connected to the connecting block 3211, and a blanking control cylinder 3213 connected to the blanking control block 3212, the blanking control block 3212 is mainly formed by connecting a blanking stopper 32121 and a blanking passing block 32122, and two upper blanking holes 321221 matched with the longitudinal magnet slot 3121 are formed on the blanking passing block 32122, two blanking holes 32111 corresponding to the upper blanking hole 321221 are formed in the connecting block 3211, and a side slot 32112 into which the blanking stopper 32121 is movably inserted is formed on the connecting block 3211. The blanking control cylinder 3213 provides driving force to drive the blanking passing block 32122 to move on the connecting block 3211, so as to control whether the two upper blanking holes 321221 correspond to the two lower blanking holes 32111, i.e., to control whether the magnets in the longitudinal magnet slot 3121 of the magnet upper charging barrel 312 can fall down from the upper blanking hole 321221 and the lower blanking holes 32111. Meanwhile, the magnet blanking assembly 322 includes two blanking through rods 3221 longitudinally disposed below the connecting block 3211 and correspondingly communicated with the two blanking holes 32111, a magnet detection optical fiber 3222 disposed on the periphery of the upper portion of the blanking through rod 3221, a blanking positioning seat 3223 disposed at the lower portion of the blanking through rod 3221 and allowing the blanking through rod 3221 to pass through, and a positioning connecting rod 3224 connected between the connecting block 3211 and the blanking positioning seat 3223. When the magnet falls from the upper blanking hole 321221 and the blanking hole 32111, the magnet directly enters the two blanking through rods 3221. In order to detect the magnets in the two blanking through rods 3221, detection openings 32210 are formed on the sides of the two blanking through rods 3221, so that the magnet detection optical fiber 3222 detects whether a magnet is located inside the upper portion of the blanking through rod 3221, if not, the magnet upper material barrel 312 can be controlled to rotate, and the next longitudinal magnet slot 3121 on the magnet upper material barrel 312 rotates to correspond to the magnet blanking mechanism 32. Meanwhile, the blanking in-place detection assembly 323 comprises an in-place detection upper base block 3231 arranged at the lower end of the blanking positioning seat 3223, a detection base 3232 arranged below the in-place detection upper base block 3231, an in-place detection lower base block 3233 arranged on the detection base 3232, and two sets of correlation detection optical fibers 3234 arranged on the detection base 3232 and penetrating to the upper end of the in-place detection lower base block 3233, wherein two first material passing holes corresponding to the blanking through rods 3221 are formed in the in-place detection upper base block 3231, and two heteropolar magnets 32331 are arranged in the in-place detection lower base block 3233 and are arranged below the two first material passing holes. The magnets in the two blanking through rods 3221 are attracted downward by the two opposite-pole magnets 32331 in the lower in-place detection base block 3233, and the fallen magnets are detected by the two groups of correlation detection optical fibers 3234 on the detection base 3232.

In the present embodiment, the correlation detection fiber 3234 and the magnet detection fiber 3222 are conventional detection fibers, and the specific operation principle of the detection fibers is the same as that of the conventional detection fibers in the field.

Specifically, as shown in fig. 1 and 5, the magnet assembling mechanism 33 includes an assembling positioning seat 331 disposed above the material-tape conveying substrate 11, a front-back pushing cylinder 332 disposed on a side edge of the material-tape conveying substrate 11, a magnet conveying plate 333 connected to an output end of the front-back pushing cylinder 332 and movably inserted into the assembling positioning seat 331, and a magnet assembling pressing component 334 disposed above the assembling positioning seat 331, wherein a movable cavity for the magnet conveying plate 333 to be movably inserted is formed in the assembling positioning seat 331, the blanking in-place detecting component 323 is disposed on the assembling positioning seat 331, and the movable cavity is located between the in-place detecting upper base block 3231 and the in-place detecting lower base block 3233; a magnet carrier 335 is arranged on the magnet conveying plate 333, two second material passing holes are respectively arranged on the assembling and positioning seat 331 and the magnet carrier 335, and at least one positioning through hole is respectively arranged on the assembling and positioning seat 331 and the magnet conveying plate 333; the magnet assembly pressing-down component 334 comprises a longitudinal installation base block 3341 arranged on the assembly positioning seat 331, a pressing-down cylinder 3342 arranged on the longitudinal installation base block 3341, a pressing-down positioning base 3343 connected to an output end of the pressing-down cylinder 3342, at least one positioning insertion column 3344 arranged on the pressing-down positioning base 3343 and facing the positioning through hole, and two magnet pressing-down columns 3345 arranged on the pressing-down positioning base 3343 and facing the second material passing hole; a downward pressing positioning block 336 is arranged in the assembling positioning seat 331, and at least two guiding insertion holes for inserting the two magnet downward pressing columns 3345 are arranged on the downward pressing positioning block 336.

When the magnet falls down, the magnet conveying plate 333 is driven to move by the front and rear pushing cylinders 332, so that the magnet carriers 335 on the magnet conveying plate 333 move to positions between the upper base block 3231 and the lower base block 3233 for in-place detection, each magnet carrier 335 is positioned between one group of correlation detection optical fibers 3234, and the second material passing holes on the magnet carriers 335 correspond to the heteropolar magnets 32331 in the lower base block 3233 for in-place detection one by one, therefore, the heteropolar magnets 32331 in the lower base block 3233 for in-place detection downwards adsorb the magnets in the blanking through rod 3221, and the magnets fall into the second material passing holes of the magnet carriers 335. Then, the front and rear pushing cylinders 332 drive the magnet conveying plate 333 to pull back, so that the second material passing hole on the magnet carrier 335 moves to correspond to the guide insertion hole on the press-down positioning block 336, and in the process that the magnet conveying plate 333 moves in the assembly positioning block 331, the magnet cannot fall down from the second material passing hole on the magnet carrier 335 by the supporting action of the bottom inside the assembly positioning block 331 until the magnet moves to the position of the guide insertion hole on the press-down positioning block 336. Finally, the down-pressure cylinder 3342 provides driving force to drive the positioning post 3344 and the magnet down-pressure post 3345 to move down, as shown in fig. 5, the positioning post 3344 is inserted into the positioning hole of the tape 10 for positioning, the magnet down-pressure post 3345 presses down the magnet in the second material passing hole of the magnet carrier 335 to enter the magnet assembling hole 201 on the lower heat-generating base 20, as shown in fig. 8, and the magnet assembling operation is completed.

As shown in fig. 1, the magnet feeding and assembling device 3 of the present embodiment further includes a heating seat positioning mechanism 34 disposed below the material belt conveying substrate 11, specifically, as shown in fig. 6 and 7, the heating seat positioning mechanism 34 includes a positioning pushing cylinder 341, a positioning pushing rod 342 connected to an output end of the positioning pushing cylinder 341, and a longitudinal positioning structure 343 disposed above the positioning pushing rod 342, wherein a step 3421 is formed on the positioning pushing rod 342, and an arc-shaped guiding surface 34211 is formed on a side surface of the step 3421; the longitudinal positioning structure 343 includes a longitudinal positioning rod 3431 disposed on the positioning pushing rod 342, and a pulley 3432 connected to the longitudinal positioning rod 3431 and slidably disposed on the positioning pushing rod 342, wherein the upper end of the longitudinal positioning rod 3431 is embedded in the assembling positioning seat 331, and the upper end of the longitudinal positioning rod 3431 is provided with a heating seat positioning groove 34311.

When the magnet pressing column 3345 is pressed downwards to press the magnet in the magnet carrier 335 into the heating base 20, the positioning pushing cylinder 341 provides a driving force to drive the positioning pushing rod 342 to move towards the longitudinal positioning structure 343, when the pulley 3432 of the longitudinal positioning structure 343 encounters the arc-shaped guiding surface 34211 on the positioning pushing rod 342, the pulley 3432 slides along the arc-shaped guiding surface 34211 to the upper end of the step 3421 while the positioning pushing rod 342 moves, thereby driving the longitudinal positioning rod 3431 to move upwards, so that the heating base 20 located right above enters the heating base positioning groove 34311, and the heating base 20 is positioned, so that the magnet pressing column 3345 can accurately press the magnet into the heating base 20, thereby preventing the heating base 20 from shifting, and improving the accuracy and speed of magnet assembly.

The magnet feeding mechanism 31, the magnet blanking mechanism 32, the magnet assembling mechanism 33 and the heating seat positioning mechanism 34 which are designed to have special structures are combined, so that the magnet feeding and magnet assembling operation can be automatically completed, the efficiency is high, the accuracy and the speed of magnet assembling can be improved, and the working efficiency is improved.

The material tape 10 in this embodiment is a metal needle tape, as shown in fig. 8.

In this embodiment, in order to facilitate the conveying of the tape 10, a tape conveying device 1 is additionally disposed in front of the magnet feeding assembly device 3, as shown in fig. 9 and 10, the tape conveying device 1 includes the above tape conveying substrate 11, two positioning strips 12 disposed on the tape conveying substrate 11 in parallel, and a tape translation mechanism 13 disposed on one of the positioning strips 12. Specifically, the tape translation mechanism 13 includes a tape translation assembly 131 and a tape positioning assembly 132 connected to the tape translation assembly 131, the tape translation assembly 131 includes a tape translation cylinder 1311 disposed on the tape conveying substrate 11, a tape translation slide rail 1312 disposed on the tape conveying substrate 11, a tape translation slider 1313 slidably disposed on the tape translation slide rail 1312, and a translation link 1314 connected to the tape translation slider 1313 and connected to an output end of the tape translation cylinder 1311, and the translation link 1314 extends to an upper end of one of the positioning strip blocks 12. The belt-moving cylinder 1311 provides a driving force to drive the moving-moving linkage 1314 and the belt-moving slider 1313 to slide back and forth on the belt-moving slide 1312. Meanwhile, the material tape positioning assembly 132 includes a longitudinal mounting block 1321 connected to the translational linkage block 1314, a material tape positioning cylinder 1322 disposed on a side edge of the longitudinal mounting block 1321, and a material tape translational positioning post 1323 connected to an output end of the material tape positioning cylinder 1322 and longitudinally movably penetrating through the translational linkage block 1314, the material tape positioning cylinder 1322 provides a driving force to drive the material tape translational positioning post 1323 to move up and down, a strip-shaped translational sliding hole 121 into which the material tape translational positioning post 1323 is movably inserted is formed on the positioning strip 12 below the translational linkage block 1314, and when the translational linkage block 1314 moves back and forth, the material tape translational positioning post 1323 is driven to move back and forth in the strip-shaped translational sliding hole 121. The tape translating assembly 131 is combined with the tape positioning assembly 132 to move the tape 10 backward. Specifically, a plurality of positioning holes are formed in the material belt 10, and the material belt translation positioning column 1323 is inserted into the positioning holes to drive the material belt 10 to move backwards.

In order to facilitate the continuous backward conveying of the material tape 10 with the plurality of heating seats 20, as shown in fig. 10, a strip-shaped material passing slot 111 is formed in the length direction of the material tape conveying substrate 11 in the present embodiment, the two positioning strip blocks 12 are oppositely disposed on two side edges of the strip-shaped material passing slot 111, and a plurality of strip-shaped empty slots 112 are respectively formed on the material tape conveying substrate 11 and located on two sides of the strip-shaped material passing slot 111. After the material belt 10 with a plurality of heating seats 20 enters the material belt conveying device 1, two side edges of the material belt 10 are positioned below two positioning strips 12, and the heating seats 20 move backwards in the strip-shaped material passing groove 111. The strip-shaped empty groove 112 is provided to reduce the contact area between the tape 10 and the surface of the tape conveying substrate 11, reduce the friction force, and facilitate the backward conveyance of the tape 10.

It should be noted that the utility model discloses a magnet pay-off assembly quality improves specific structure, and to concrete control mode, is not the innovation point of the utility model. To the cylinder, motor, detection optic fibre and other parts that the utility model relates to, can be general standard component or the part that technical staff in this field knows, its structure, principle and control mode are technical manual and learn or learn through conventional experimental method for technical staff in this field.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that other structures obtained by adopting the same or similar technical features as the above embodiments of the present invention are all within the protection scope of the present invention.

Claims (7)

1. A magnet feeding and assembling device is characterized by comprising a magnet feeding mechanism, a magnet blanking mechanism arranged below the side of the magnet feeding mechanism and positioned above a material belt conveying substrate, and a magnet assembling mechanism arranged on the material belt conveying substrate, wherein the magnet assembling mechanism comprises an assembling positioning seat arranged above the material belt conveying substrate, a front and back pushing cylinder arranged on the side edge of the material belt conveying substrate, a magnet conveying plate connected to the output end of the front and back pushing cylinder and movably inserted into the assembling positioning seat, and a magnet assembling pressing component arranged above the assembling positioning seat; a magnet carrier is arranged on the magnet conveying plate, two second material passing holes are respectively formed in the assembling and positioning seat and the magnet carrier, and at least one positioning through hole is respectively formed in the assembling and positioning seat and the magnet conveying plate; the magnet assembly pressing component comprises a longitudinal installation base block arranged on the assembly positioning seat, a pressing cylinder arranged on the longitudinal installation base block, a pressing positioning base connected to the output end of the pressing cylinder, at least one positioning insertion column arranged on the pressing positioning base and facing the positioning through hole, and two magnet pressing columns arranged on the pressing positioning base and facing the second material passing hole.

2. The magnet feeding and assembling device according to claim 1, wherein a lower pressing and positioning block is disposed in the assembling and positioning seat, and at least two guiding insertion holes for inserting the two magnet lower pressing posts are formed in the lower pressing and positioning block.

3. A magnet feeding assembly apparatus as claimed in claim 1, wherein the magnet feeding mechanism includes a base plate, a magnet charging barrel disposed on the base plate, and a rotary driving assembly disposed at a lower middle portion of the base plate and connected to the magnet charging barrel, wherein a plurality of longitudinal magnet insertion slots are formed on the magnet charging barrel.

4. A magnet feed assembly apparatus as claimed in claim 3, in which the rotary drive assembly includes a rotary drive servomotor, a speed reducer connected to the output of the rotary drive servomotor, and a keyless bushing for connecting the output of the speed reducer and the magnet feed cylinder together.

5. A magnet feeding and assembling device as claimed in claim 3, wherein the magnet blanking mechanism comprises a magnet blanking control assembly disposed on one side of the chassis, a magnet blanking assembly disposed below the magnet blanking control assembly, and a blanking-in-place detection assembly disposed below the magnet blanking assembly, wherein the magnet blanking control component comprises a connecting block inserted on the side edge of the chassis, a blanking control block movably connected with the connecting block, and a blanking control cylinder connected with the blanking control block, the blanking control block is mainly formed by connecting a blanking stop block and a blanking passing block, two upper blanking holes matched with the longitudinal magnet slots are formed on the blanking passing block, two blanking holes corresponding to the upper blanking holes are formed on the connecting block, and a side slot for the movable insertion of the blanking stop block is formed on the connecting block; the magnet blanking assembly comprises two blanking through rods which are longitudinally arranged below the connecting block and correspondingly communicated with the two blanking holes, a magnet detection optical fiber arranged on the periphery of the upper part of the blanking through rod, a blanking positioning seat arranged on the lower part of the blanking through rod and through which the blanking through rod passes, and a positioning connecting rod connected between the connecting block and the blanking positioning seat; the blanking in-place detection assembly comprises an in-place detection upper base block arranged at the lower end of a blanking positioning seat, a detection base arranged below the in-place detection upper base block, an in-place detection lower base block arranged on the detection base, and two groups of correlation detection optical fibers arranged on the detection base and penetrating to the upper end of the in-place detection lower base block, wherein two first material passing holes corresponding to blanking through rods are formed in the in-place detection upper base block, and two heteropolar magnets are arranged below the two first material passing holes in the in-place detection lower base block.

6. The magnet feeding and assembling device according to claim 5, wherein a movable cavity for movably inserting the magnet conveying plate is formed in the assembling positioning seat, the blanking in-place detecting assembly is disposed on the assembling positioning seat, and the movable cavity is located between the in-place detecting upper base block and the in-place detecting lower base block.

7. The magnet feeding and assembling device according to claim 1, further comprising a heating seat positioning mechanism disposed below the carrier tape conveying substrate, the heating seat positioning mechanism comprising a positioning pushing cylinder, a positioning pushing rod connected to an output end of the positioning pushing cylinder, and a longitudinal positioning structure disposed above the positioning pushing rod, wherein a step is formed on the positioning pushing rod, and an arc-shaped guide surface is formed on a side surface of the step; the longitudinal positioning structure comprises a longitudinal positioning rod arranged on the positioning push rod and a pulley which is connected with the longitudinal positioning rod and is arranged on the positioning push rod in a sliding manner, the upper end of the longitudinal positioning rod is embedded into the assembly positioning seat, and the upper end of the longitudinal positioning rod is provided with a heating seat positioning groove.

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