CN219349981U - Separated inductance network transformer assembly equipment - Google Patents

Abstract

The utility model discloses split type inductance network transformer assembly equipment which comprises a frame, a patch feeding module, a magnetic core feeding module, a jacking module, a gluing module, a blanking carrying module and an oven module, wherein the patch feeding module is arranged on the frame; the surface mounting feeding module, the magnetic core feeding module, the jacking module, the gluing module, the blanking carrying module and the baking module are fixedly arranged on the frame; the oven module is arranged below the blanking carrying module. The utility model has the advantages of improving the production efficiency, reducing the cost of machinery and labor, improving the product quality and the like which are not possessed by the prior equipment.

Description

Separated inductance network transformer assembly equipment

Technical Field

The utility model relates to the field of transformer assembly, in particular to split-type inductance network transformer assembly equipment.

Background

The existing assembly equipment of the separated inductance network transformer has the following problems: the efficiency is low, the rubber coating overflows, the paster is not flush, and the defective rate of inductance is high.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides a split type inductance network transformer assembly device

The technical scheme adopted for solving the technical problems is as follows:

a split type inductance network transformer assembly device comprises a frame, a patch feeding module, a magnetic core feeding module, a jacking module, a gluing module, a blanking carrying module and an oven module; the surface mounting feeding module, the magnetic core feeding module, the jacking module, the gluing module, the blanking carrying module and the baking module are fixedly arranged on the frame; the oven module is arranged below the blanking carrying module.

In the above structure, the oven module comprises an oven, a conveyor belt, a driving roller, a driven roller and a motor; the output end of the motor is provided with a coupler; the conveyor belt is wound on the driving roller and the driven roller; the conveyor belt is arranged below the oven; the coupling is connected with the driving roller.

In the above structure, the blanking conveying module comprises a blanking bracket; a transverse plate is arranged on the blanking bracket; the transverse plate is sleeved with a first sliding block, and a fixing plate is arranged on the first sliding block.

In the structure, a sensor is arranged on the blanking bracket; the first sliding block is provided with an induction steel sheet.

In the structure, the fixed plate is provided with a screw rod; a Z-axis panel is sleeved on the screw rod; a suction nozzle fixing plate is arranged on the Z-axis panel; the suction nozzle fixing plate is provided with a chuck; a first guide rail is arranged on the Z-axis panel; a vertical sliding block is embedded on the first guide rail; a blanking cylinder is arranged on the Z-axis panel; an L-shaped connecting plate is arranged at the output end of the blanking cylinder; the other end of the L-shaped connecting plate is connected with the clamping head; the L-shaped connecting plate is connected with the vertical sliding block.

In the above structure, the patch feeding module comprises a carrying cylinder, a first magnetic core, a first feeding circular shock and a first discharging plate; the first magnetic core is arranged on the rack; the first feeding circular shock is arranged on the first magnetic core; the first discharging plate is arranged at the edge of the first feeding circular shock.

In the structure, a carrying cylinder bracket is arranged on the frame; the carrying cylinder is fixedly arranged on the carrying cylinder bracket; the carrying cylinder bracket is provided with a second guide rail; a second sliding block is embedded on the second guide rail; the second sliding block is provided with an air cylinder; a suction nozzle is arranged at the output end of the air cylinder; the suction nozzle is arranged right above the first discharging plate; a connecting block is arranged between the output end of the carrying cylinder and the second sliding block and used for connecting the carrying cylinder and the second sliding block.

In the above structure, the magnetic core feeding module comprises a second magnetic core, a second feeding circular shock and a second discharging plate; the second magnetic core is arranged on the rack; the second feeding circular shock is arranged on the second magnetic core; the second discharging plate is arranged at the edge of the second feeding circular shock.

In the structure, the material ejection module comprises a material ejection cylinder, a material ejection rod, a limiting block and a limiting elastic piece; the frame is provided with a liftout cylinder bracket; the ejection cylinder is fixedly arranged on the ejection cylinder bracket; the ejection rod is arranged at the output end of the ejection cylinder; the limiting block is arranged on the frame; a limiting elastic sheet is arranged at the top end of the limiting block; a magnetic core is arranged at the top end of the material ejection rod; the material ejection rod is arranged below the limiting elastic sheet; the ejector rod is arranged at the second discharging plate.

In the above structure, the glue spreading module comprises a glue dispensing group and a glue scraping group.

In the above structure, the dispensing group comprises a third guide rail, a dispensing horizontal moving cylinder, a dispensing vertical moving cylinder and a dispensing head; a dispensing cylinder bracket is arranged on the frame; the third guide rail is fixedly arranged on the dispensing cylinder bracket; a third sliding block is embedded on the third guide rail; the glue-dispensing translation air cylinder is fixedly arranged on the third sliding block; the output end of the dispensing horizontal moving cylinder is connected with a dispensing cylinder bracket; the dispensing vertical moving cylinder is fixedly arranged on the third sliding block; the output end of the dispensing vertical moving cylinder is provided with a dispensing head mounting plate; the dispensing head is arranged on the dispensing head mounting plate.

In the above structure, the scraping group comprises a scraping bracket; a rotary cylinder is arranged on the scraping support; the output end of the rotary cylinder is provided with a glue groove; the scraping support is provided with a scraping plate; the scraping plate is arranged in the glue groove; the scraping plate is arranged on the side edge of the dispensing head; the dispensing head is arranged above the glue groove.

The beneficial effects of the utility model are as follows: the utility model provides split type inductance network transformer assembly equipment which comprises a frame, a patch feeding module, a magnetic core feeding module, a jacking module, a gluing module, a blanking carrying module and an oven module, wherein the frame is provided with a plurality of magnetic cores; the surface mounting feeding module, the magnetic core feeding module, the jacking module, the gluing module, the blanking carrying module and the baking module are fixedly arranged on the frame; the oven module is arranged below the blanking carrying module. The utility model realizes high-efficiency, high-quality and low-cost preparation of the inductance network transformer, solves the problems of low efficiency, high cost, high product reject ratio and the like of the inductance network transformer prepared by the existing equipment, and can greatly improve the production efficiency, reduce the cost and improve the product quality in the use process.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a schematic view of the assembly of the present utility model;

FIG. 2 is a schematic view of the assembly of the oven module of the present utility model;

FIG. 3 is an assembled schematic view of the blanking transfer module of the present utility model;

FIG. 4 is a schematic diagram of an assembly of a patch feed module of the present utility model;

FIG. 5 is a schematic diagram of the assembly of a magnetic core feed module of the present utility model;

FIG. 6 is a schematic view of the assembly of the ejector module of the present utility model;

fig. 7 is a schematic view of the assembly of the glue module according to the utility model.

Detailed Description

The conception, specific structure, and technical effects produced by the present utility model will be clearly and completely described below with reference to the embodiments and the drawings to fully understand the objects, features, and effects of the present utility model. It is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and that other embodiments obtained by those skilled in the art without inventive effort are within the scope of the present utility model based on the embodiments of the present utility model. In addition, all the coupling/connection relationships referred to in the patent are not direct connection of the single-finger members, but rather, it means that a better coupling structure can be formed by adding or subtracting coupling aids depending on the specific implementation. The technical features in the utility model can be interactively combined on the premise of no contradiction and conflict.

Referring to fig. 1, a split type inductance network transformer assembly device includes a frame 001, a patch feeding module 005, a magnetic core feeding module 004, a jacking module 007, a gluing module 006, a blanking carrying module 003 and an oven module 002; the patch feeding module 005, the magnetic core feeding module 004, the ejection module 007, the gluing module 006, the blanking carrying module 003 and the oven module 002 are fixedly arranged on the frame 001; the oven module 002 is disposed below the blanking transfer module 003.

As shown in fig. 2, the oven module 002 includes an oven 205, a conveyor 204, a driving roller 203, a driven roller 206, and a motor 201; a coupling 202 is arranged on the output end of the motor 201; the conveyor belt 204 is wound on the driving roller 203 and the driven roller 206; the conveyor belt 204 is arranged below the oven 205; the coupling 202 is connected to a drive roller 203.

As shown in fig. 3, the blanking conveying module includes a blanking bracket 301; a transverse plate 302 is arranged on the blanking bracket 301; the transverse plate 302 is sleeved with a first sliding block 303, and a fixing plate 311 is arranged on the first sliding block 303.

A sensor 312 is arranged on the blanking bracket 301; the first slider 303 is provided with an induction steel sheet.

A screw rod is arranged on the fixed plate 311; a Z-axis panel 310 is sleeved on the screw rod; the Z-axis panel 310 is provided with a suction nozzle fixing plate 307; the suction nozzle fixing plate 307 is provided with a chuck 305; the Z-axis panel 310 is provided with a first guide rail 308; a vertical sliding block 306 is embedded on the first guide rail 308; a blanking cylinder 309 is arranged on the Z-axis panel 310; an L-shaped connecting plate 304 is arranged at the output end of the blanking cylinder 309; the other end of the L-shaped connecting plate 304 is connected with a chuck 305; the "L" shaped connection plate 304 is connected to a vertical slider 306.

As shown in fig. 4, the patch feeding module 005 includes a carrying cylinder 505, a first magnetic core 501, a first feeding circular shock 503, and a first discharging plate 502; the first magnetic core 501 is arranged on the rack 001; the first feeding circular shock 503 is arranged on the first magnetic core 501; the first discharging plate 502 is arranged at the edge of the first feeding circular shock 503.

A carrying cylinder bracket 504 is arranged on the frame 001; the carrying cylinder 505 is fixedly arranged on the carrying cylinder bracket 504; a second guide rail 508 is disposed on the carrying cylinder bracket 504; a second sliding block 509 is embedded on the second guide rail 508; the second sliding block 509 is provided with a cylinder 506; a suction nozzle 510 is arranged on the output end of the air cylinder 506; the suction nozzle 510 is arranged right above the first discharging plate 502 to suck materials; a connection block 507 is disposed between the output end of the carrying cylinder 505 and the second slider 509 for connecting the carrying cylinder 505 and the second slider 509.

As shown in fig. 5, the magnetic core feeding module 004 includes a second magnetic core 402, a second feeding circular shock 401 and a second discharging plate 403; the second magnetic core 402 is disposed on the frame 001; the second feeding circular shock 401 is arranged on the second magnetic core 402; the second discharging plate 403 is arranged at the edge of the second feeding circular shock 401.

As shown in fig. 6, the ejector module 007 includes an ejector cylinder 705, an ejector rod 704, a stopper 701, and a stopper elastic piece 702; a liftout cylinder bracket 706 is arranged on the frame 001; the ejection cylinder 705 is fixedly arranged on the ejection cylinder bracket 706; the ejector rod 704 is arranged on the output end of the ejector cylinder 705; the limiting block 701 is arranged on the frame 001; a limiting spring piece 702 is arranged at the top end of the limiting block 701; a magnetic core 703 is provided on the top end of the ejector pin 704; the ejector rod 704 is arranged below the limiting elastic sheet 702; the ejector pins 704 are arranged at the second take-off plate 403.

As shown in fig. 7, the glue module 006 includes a glue dispensing group and a glue scraping group.

The dispensing group comprises a third guide rail 604, a dispensing translation air cylinder 602, a dispensing vertical movement air cylinder 605 and a dispensing head 607; a dispensing cylinder bracket 601 is arranged on the frame 001; the third guide rail 604 is fixedly arranged on the dispensing cylinder support 601; a third sliding block 603 is embedded on the third guide rail 604; the dispensing horizontal moving cylinder 602 is fixedly arranged on the third sliding block 603; the output end of the dispensing horizontal moving cylinder 602 is connected with a dispensing cylinder bracket 601; the dispensing vertical moving cylinder 605 is fixedly arranged on the third sliding block 603; the output end of the dispensing vertical moving cylinder 605 is provided with a dispensing head mounting plate 606; the dispensing head 607 is disposed on a dispensing head mounting plate 606.

The scraping group comprises a scraping bracket 608; a rotary cylinder 609 is arranged on the scraping bracket 608; the output end of the rotary cylinder 609 is provided with a glue groove 610; the scraping support 608 is provided with a scraping plate 611; the scraping plate 611 is arranged in the glue groove 610; the scraping plate 611 is arranged at the side edge of the dispensing head 607 so as to conveniently scrape excessive sizing material for the product; the dispensing head 607 is disposed above the glue slot 610.

While the preferred embodiment of the present utility model has been described in detail, the present utility model is not limited to the embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present utility model, and these equivalent modifications or substitutions are included in the scope of the present utility model as defined in the appended claims.

Claims (10)

1. The utility model provides a disconnect-type inductance network transformer equipment, its characterized in that: the device comprises a frame, a patch feeding module, a magnetic core feeding module, a jacking module, a gluing module, a blanking carrying module and an oven module; the surface mounting feeding module, the magnetic core feeding module, the jacking module, the gluing module, the blanking carrying module and the baking module are fixedly arranged on the frame; the oven module is arranged below the blanking conveying module; the oven module comprises an oven, a conveyor belt, a driving roller, a driven roller and a motor; the blanking carrying module comprises a blanking bracket; a transverse plate is arranged on the blanking bracket; the patch feeding module comprises a carrying cylinder, a first magnetic core, a first feeding circular shock and a first discharging plate; the magnetic core feeding module comprises a second magnetic core, a second feeding circular shock and a second discharging plate; the ejection module comprises an ejection cylinder, an ejection rod, a limiting block and a limiting elastic piece; the gluing module comprises a dispensing group and a scraping group; the dispensing group comprises a third guide rail, a dispensing horizontal moving cylinder, a dispensing vertical moving cylinder and a dispensing head.

2. The split inductor network transformer assembly set-up of claim 1, wherein: the output end of the motor is provided with a coupler; the conveyor belt is wound on the driving roller and the driven roller; the conveyor belt is arranged below the oven; the coupling is connected with the driving roller.

3. The split inductor network transformer assembly set-up of claim 1, wherein: the transverse plate is sleeved with a first sliding block, and a fixed plate is arranged on the first sliding block; a sensor is arranged on the blanking bracket; the first sliding block is provided with an induction steel sheet.

4. A split inductance network transformer assembly device according to claim 3, wherein: a screw rod is arranged on the fixed plate; a Z-axis panel is sleeved on the screw rod; a suction nozzle fixing plate is arranged on the Z-axis panel; the suction nozzle fixing plate is provided with a chuck; a first guide rail is arranged on the Z-axis panel; a vertical sliding block is embedded on the first guide rail; a blanking cylinder is arranged on the Z-axis panel; an L-shaped connecting plate is arranged at the output end of the blanking cylinder; the other end of the L-shaped connecting plate is connected with the clamping head; the L-shaped connecting plate is connected with the vertical sliding block.

5. The split inductor network transformer assembly set-up of claim 1, wherein: the first magnetic core is arranged on the rack; the first feeding circular shock is arranged on the first magnetic core; the first discharging plate is arranged at the edge of the first feeding circular shock.

6. The split inductor network transformer assembly set-up of claim 1, wherein: a carrying cylinder bracket is arranged on the frame; the carrying cylinder is fixedly arranged on the carrying cylinder bracket; the carrying cylinder bracket is provided with a second guide rail; a second sliding block is embedded on the second guide rail; the second sliding block is provided with an air cylinder; a suction nozzle is arranged at the output end of the air cylinder; the suction nozzle is arranged right above the first discharging plate; a connecting block is arranged between the output end of the carrying cylinder and the second sliding block and used for connecting the carrying cylinder and the second sliding block.

7. The split inductor network transformer assembly set-up of claim 1, wherein: the second magnetic core is arranged on the rack; the second feeding circular shock is arranged on the second magnetic core; the second discharging plate is arranged at the edge of the second feeding circular shock.

8. The split inductor network transformer assembly set-up of claim 7, wherein: the frame is provided with a liftout cylinder bracket; the ejection cylinder is fixedly arranged on the ejection cylinder bracket; the ejection rod is arranged at the output end of the ejection cylinder; the limiting block is arranged on the frame; a limiting elastic sheet is arranged at the top end of the limiting block; a magnetic core is arranged at the top end of the material ejection rod; the material ejection rod is arranged below the limiting elastic sheet; the ejector rod is arranged at the second discharging plate.

9. The split inductor network transformer assembly set-up of claim 1, wherein: a dispensing cylinder bracket is arranged on the frame; the third guide rail is fixedly arranged on the dispensing cylinder bracket; a third sliding block is embedded on the third guide rail; the glue-dispensing translation air cylinder is fixedly arranged on the third sliding block; the output end of the dispensing horizontal moving cylinder is connected with a dispensing cylinder bracket; the dispensing vertical moving cylinder is fixedly arranged on the third sliding block; the output end of the dispensing vertical moving cylinder is provided with a dispensing head mounting plate; the dispensing head is arranged on the dispensing head mounting plate.

10. The split inductor network transformer assembly set-up of claim 9, wherein: the scraping group comprises a scraping bracket; a rotary cylinder is arranged on the scraping support; the output end of the rotary cylinder is provided with a glue groove; the scraping support is provided with a scraping plate; the scraping plate is arranged in the glue groove; the scraping plate is arranged on the side edge of the dispensing head; the dispensing head is arranged above the glue groove.

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