CN116141732A

CN116141732A - Middle die feeding machine

Info

Publication number: CN116141732A
Application number: CN202310100920.XA
Authority: CN
Inventors: 杨昌瑞; 李保玉; 叶珠建; 臧俊涛; 吕钢
Original assignee: HERUI ELECTRONIC (ZHONGSHAN) CO Ltd
Current assignee: HERUI ELECTRONIC (ZHONGSHAN) CO Ltd
Priority date: 2023-02-07
Filing date: 2023-02-07
Publication date: 2023-05-23

Abstract

The invention discloses a middle die feeding machine, which comprises: the device comprises a feeding table, a discharging table, a feeding mechanism, a powder filling mechanism, a pressing die and a carrying mechanical arm; the feeding mechanism can move close to or far away from the feeding table and drive the jig plate to move; the powder filling mechanism can fill powder into the jig tray; the material pressing die can compact and form materials in the jig tray; the feeding mechanism, the powder filling mechanism, the pressing die and the blanking table are distributed around the conveying mechanical arm, and the conveying mechanical arm can drive the jig plate at the feeding mechanism to sequentially move to the powder filling mechanism, the pressing die and the blanking table. The material is conveyed to each mechanism through the single conveying mechanical arm, and the mechanisms are distributed around the conveying mechanical arm, so that the conveying cost required by conveying the jig tray between the mechanisms can be effectively reduced, the energy-saving and consumption-reducing effects can be achieved, the whole occupied area can be effectively reduced, and convenience is brought to the operation of staff and the placement of other machines.

Description

Middle die feeding machine

Technical Field

The invention relates to the field of inductance forming, in particular to a middle die feeding machine.

Background

As is well known, in the process of manufacturing and forming the inductor, magnetic powder is required to be filled in a coil frame in a jig disc, then the coil frame and the jig disc are compacted by a die, and finally the whole jig disc is cooled, so that subsequent operation can be performed. However, these processes are usually performed by a plurality of machines, and a corresponding transporting mechanism needs to be provided between every two machines to ensure that the jig tray can smoothly run through the whole process. However, such a process flow not only involves high costs due to the multiple transportation, but also requires a large enough area in the factory to house the individual transport mechanisms.

Disclosure of Invention

The present invention aims to solve at least one of the technical problems existing in the prior art. Therefore, the invention provides the middle die feeding machine, which can reduce the cost and the occupied area of the conveying mechanism.

According to an embodiment of the first aspect of the invention, the middle die feeding machine comprises: the device comprises a feeding table, a discharging table, a feeding mechanism, a powder filling mechanism, a pressing die and a carrying mechanical arm; the feeding mechanism can move close to or far away from the feeding table and drive the jig plate to move; the powder filling mechanism can fill powder into the jig tray; the material pressing die can compact and form materials in the jig tray; the feeding mechanism, the powder filling mechanism, the pressing die and the discharging table encircle the conveying mechanical arm, and the conveying mechanical arm can drive a jig disc at the feeding mechanism to sequentially move to the powder filling mechanism, the pressing die and the discharging table.

The middle die feeding machine provided by the embodiment of the invention has at least the following beneficial effects: after the jig plate is driven by the feeding mechanism at the feeding table, the carrying mechanical arm can move to the feeding mechanism and drive the jig plate to leave the feeding mechanism. After the handling mechanical arm carries the jig tray from the feeding mechanism to the powder filling mechanism, the powder filling mechanism fills powder into the jig tray, and then the handling mechanical arm carries away the jig tray again. Then, the jig plate is conveyed to the pressing die by the conveying mechanical arm, and the conveying mechanical arm is compacted and formed by the pressing die. And finally, driving the compacted and molded jig plate to a blanking table by the carrying mechanical arm.

The material is conveyed to each mechanism through the single conveying mechanical arm, and the mechanisms are distributed around the conveying mechanical arm, so that the conveying cost required by conveying the jig tray between the mechanisms can be effectively reduced, the energy-saving and consumption-reducing effects can be achieved, the whole occupied area can be effectively reduced, and convenience is brought to the operation of staff and the placement of other machines.

According to some embodiments of the invention, the feeding mechanism comprises a first bearing seat, wherein the first bearing seat is connected with a displacement assembly, and the displacement assembly can drive the first bearing seat to move close to or far away from the feeding table.

According to some embodiments of the invention, a protection piece is arranged at the side of the loading table, the carrying mechanical arm and the loading table are respectively positioned at two sides of the protection piece, and the first bearing bracket can drive the jig plate to move through the protection piece.

According to some embodiments of the invention, the powder filling mechanism comprises a second bearing seat and a powder chamber, the handling mechanical arm can drive the jig tray to move to the second bearing seat, and the second bearing seat can drive the jig tray to move to the powder chamber; the powder chamber is provided with a powder filling punch, and the powder filling punch can move to be close to the powder chamber and punch powder in the powder chamber to the jig disc.

According to some embodiments of the invention, a plurality of powder falling holes are formed in the bottom of the powder chamber, and the second bearing seat can drive the jig tray to move to the position below the powder chamber; the powder filling punch is connected with a powder filling driving piece, and the powder filling driving piece can drive the powder filling punch to pass through the powder falling hole and push powder to the jig disc.

According to some embodiments of the invention, a powder bin is arranged at the powder chamber, the powder bin is connected with a displacement driving piece, and the powder bin is provided with a powder outlet towards the bottom of the powder chamber; the displacement driving piece can drive the powder bin to move and enable the powder outlet to reciprocate in the powder bin.

According to some embodiments of the invention, the displacement driving member is connected with a turnover driving member, and the turnover driving member is connected with the powder bin and can drive the powder bin to turn over; the powder bin can be turned over to the state that the powder outlet is mutually attached to the bottom wall of the powder bin.

According to some embodiments of the invention, the material pressing die is provided with a preheating piece, and the carrying mechanical arm can drive the material to move to the preheating piece and perform preheating operation.

According to some embodiments of the invention, a working position is arranged in the material pressing die, a third bearing seat is arranged at the side of the material pressing die, and the third bearing seat reciprocates between the preheating piece and the material pressing die; the material pressing die is internally provided with a carrying piece, the carrying piece reciprocates between the outside of the material pressing die and the working position, and the carrying mechanical arm can move to be close to the carrying piece after the material pressing die is moved out.

According to some embodiments of the invention, a cooling mechanism is arranged at the side of the blanking table, and the cooling mechanism can cool the jig tray.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of a middle mold feeder in an embodiment of the present invention;

FIG. 2 is a schematic view of a loading station of the intermediate die loader shown in FIG. 1;

FIG. 3 is a schematic view of a loading mechanism of the middle mold loader shown in FIG. 1;

FIG. 4 is a schematic view of a powder filling mechanism of the middle mold feeder shown in FIG. 1;

FIG. 5 is a schematic view of a powder chamber of the intermediate die feeder shown in FIG. 1;

fig. 6 is a schematic view of the middle die feeder shown in fig. 1 in a press die.

Reference numerals: a loading table 100;

a feeding mechanism 200; a first support bracket 210; jacking cylinder 220; a displacement assembly 230; a protector 270; a loading rail 280;

a carrying robot 300;

a powder filling mechanism 400; powder filling punch 410; a powder filling drive 415; a second support bracket 420; a displacement cylinder 425; a powder chamber 430; a powder bin 440; a displacement driver 450; flip drive 470;

a pre-heating member 500; a third support bracket 530; a carrier 540; a carrying rail 545; a work station 550;

a pressing die 600; a blanking table 800; a cooling mechanism 900; a heat radiation fan 950;

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

In the description of the present invention, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present invention and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present invention, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present invention can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

Referring to fig. 1, a middle mold feeder includes: a feeding table 100, a discharging table 800, a feeding mechanism 200, a powder filling mechanism 400, a pressing die 600 and a carrying mechanical arm 300; the feeding mechanism 200 can move close to or far from the feeding table 100 and drive the jig plate to move; the powder filling mechanism 400 can fill powder into the jig tray; the material pressing die 600 can compact and shape the materials in the jig tray; the feeding mechanism 200, the powder filling mechanism 400, the pressing die 600 and the blanking table 800 are distributed around the carrying mechanical arm 300, and the carrying mechanical arm 300 can drive a jig tray at the feeding mechanism 200 to sequentially move to the powder filling mechanism 400, the pressing die 600 and the blanking table 800. After the jig tray is driven by the feeding mechanism 200 at the feeding table 100, the carrying mechanical arm 300 can move to the feeding mechanism 200 and drive the jig tray to leave the feeding mechanism 200. After the handling mechanical arm 300 carries the jig tray from the feeding mechanism 200 to the powder filling mechanism 400, the powder filling mechanism 400 fills the powder into the jig tray, and then the handling mechanical arm 300 carries the jig tray again. Then, the jig tray is transported to the pressing mold 600 by the handling robot 300, and the pressing mold 600 performs compaction molding on the handling robot 300. Finally, the handling robot 300 drives the compacted and formed jig tray to the blanking table 800. The materials are conveyed to each mechanism through the single conveying mechanical arm 300, and the mechanisms are distributed around the conveying mechanical arm 300, so that the conveying cost required by conveying the jig tray between the mechanisms can be effectively reduced, the effects of energy conservation and consumption reduction can be achieved, the whole occupied area can be effectively reduced, and convenience is brought to the operation of staff and the placement of other machines.

Specifically, the loading table 100 and the unloading table 800 are located at two ends of the same machine. Of course, the feeding stage 100 and the discharging stage 800 may be located on different machines, and the specific embodiment may be adjusted according to actual needs, which is not limited herein.

In some embodiments, referring to fig. 3, the feeding mechanism 200 includes a first support bracket 210, the first support bracket 210 is connected to a displacement assembly 230, and the displacement assembly 230 can drive the first support bracket 210 to move close to or away from the feeding table 100. After the displacement assembly 230 drives the first support bracket 210 to move to the loading station 100, the first support bracket 210 can remove the jig tray at the loading station 100. Then, the displacement assembly 230 can drive the jig tray to move away from the loading table 100 through the first supporting seat 210, so that the jig tray on the first supporting seat 210 can be separated from other jig trays, and further the subsequent processing operation can be conveniently performed.

Specifically, the loading platform 100 is provided with a loading rail 280, and the displacement assembly 230 includes an air cylinder, which is connected to the first bearing bracket 210 and can drive the first bearing bracket to move along the loading rail 280. The first support base 210 is further connected to a lifting cylinder 220, and when the first support base 210 moves below the loading platform 100, the first support base 210 can be lifted up by the lifting cylinder 220, so that the first support base 210 can be conveniently removed from the loading platform 100.

In some embodiments, referring to fig. 2, a protection member 270 is disposed beside the loading table 100, the handling robot 300 and the loading table 100 are respectively located at two sides of the protection member 270, and the first bearing bracket 210 can drive the jig tray to move through the protection member 270. The protection member 270 can effectively block the handling robot 300, so that the handling robot 300 cannot move to the side where the upper platform 100 is located, and further avoid collision or impact to the staff. The first supporting seat 210 can drive the jig tray to pass through the protecting member 270, so as to ensure that the feeding operation can be performed smoothly.

In some embodiments, referring to fig. 4, the powder filling mechanism 400 includes a second support seat 420 and a powder chamber 430, the handling robot 300 can drive the jig tray to move to the second support seat 420, and the second support seat 420 can drive the jig tray to move to the powder chamber 430; the powder chamber 430 is provided with a powder filling punch 410, and the powder filling punch 410 can move close to the powder chamber 430 and punch powder in the powder chamber 430 to the jig tray. After the handling robot 300 transfers the jig tray onto the second support base 420, the second support base 420 can drive the jig tray to move to the powder chamber 430. The powder filling ram 410 then moves closer to the powder chamber 430 and presses the powder in the powder chamber 430 into the coil form in the jig tray, thereby directly and efficiently completing the powder filling operation.

Specifically, the powder filling punch 410 is provided with a plurality of columns, and the number of the columns is the same as the shape and the distribution of the coil frames distributed on the jig tray.

In some embodiments, referring to fig. 5, a plurality of powder falling holes are formed at the bottom of the powder chamber 430, and the second support seat 420 can drive the jig tray to move below the powder chamber 430; the powder filling punch 410 is connected with a powder filling driving piece 415, and the powder filling driving piece 415 can drive the powder filling punch 410 to pass through the powder falling hole and push powder to the jig disc. The powder falling hole can be used for carrying out relative positioning between powder and the powder filling punch 410 and between the powder filling punch 410 and the jig tray in advance and effectively limiting the single falling amount of the powder, so that the powder filling punch 410 can be effectively ensured to smoothly fill the powder into the jig tray when being pressed down, and further the powder filling operation is completed.

In some embodiments, referring to fig. 5, a powder bin 440 is provided at the powder chamber 430, the powder bin 440 is connected to a displacement drive 450, and the powder bin 440 has a powder outlet toward the bottom of the powder chamber 430; the displacement driving member 450 can drive the powder bin 440 to move and make the powder outlet reciprocate in the powder bin 440. When the displacement driving member 450 drives the powder bin 440 to displace relative to the powder chamber 430, the powder outlet of the powder bin 440 can continuously supply powder, and the powder is tiled at the bottom of the powder chamber 430 through the continuous movement of the powder bin 440, so that the powder filling operation of the subsequent powder filling punch 410 is facilitated.

Specifically, the powder bin 440 is located at the powder outlet and has a straight plane corner, and can achieve the pushing and tiling effect on the powder through the straight plane corner. It is contemplated that the powder may be poured directly into the powder chamber 430 and spread by brushing or the like. The specific embodiments can be adjusted according to actual needs, and are not limited herein.

Further, the displacement driver 450 is a cylinder. Of course, the displacement driving member 450 may be other components, such as a hydraulic cylinder (not shown). The specific embodiments can be adjusted according to actual needs, and are not limited herein.

In some embodiments, referring to FIG. 5, a flip drive 470 is coupled to the displacement drive 450, the flip drive 470 being coupled to the powder cartridge 440 and capable of driving it to flip; the powder bin 440 can be flipped over until the powder outlet engages the bottom wall of the powder bin 440. The overturning driving member 470 can drive the powder bin 440 to overturn relative to the bottom of the powder bin 440, so as to directly and effectively change the width between the powder outlet and the bottom wall of the powder bin 440, thereby effectively achieving the effect of controlling the thickness of the powder tiling. When the powder is not required to be continuously supplied, the overturning driving piece 470 can drive the powder outlet to be attached to the bottom of the powder bin 440, so that the blocking effect of the powder outlet is achieved, the powder cannot continuously flow out, and the supply of the powder is smoothly stopped.

Further, the overturning driving member 470 is an air cylinder, the powder bin 440 is connected to a rotating shaft, and the air cylinder can drive the powder bin 440 to overturn relative to the rotating shaft. Of course, the displacement driving member 450 may be other components, such as a hydraulic cylinder (not shown). The specific embodiments can be adjusted according to actual needs, and are not limited herein.

In some embodiments, referring to fig. 6, a preheating piece 500 is disposed at a material pressing mold 600, and the handling robot 300 can drive a material to move to the preheating piece 500 and perform a preheating operation. The pressing die 600 generally requires hot pressing before compacting the material in the jig tray. The preheating piece 500 can be preheated by the jig tray which is ready to enter the material pressing mold 600, so that the temperature of the jig tray is initially raised, and further, the problem that the jig tray directly performs high-volume temperature difference change in the material pressing mold 600 and causes damage to materials is effectively avoided.

Specifically, the pre-heater 500 is an electrically heated plate. Of course, the preheating member 500 may be other components, such as a burner (not shown). The specific embodiments can be adjusted according to actual needs, and are not limited herein.

In some embodiments, referring to fig. 6, a working station 550 is disposed in the pressing mold 600, and a third support bracket 530 is disposed at a side of the pressing mold 600, and the third support bracket 530 reciprocates between the pre-heater 500 and the pressing mold 600; the carrying member 540 is disposed in the pressing mold 600, the carrying member 540 reciprocates between the outside of the pressing mold 600 and the working position 550, and the carrying mechanical arm 300 can move close to the carrying member 540 after the pressing mold 600 is moved out. The swage tool 600 will perform the swage operation at station 550. After the jig tray is preheated, the third support bracket 530 will move to the preheating piece 500 and transfer the jig tray to the working position 550, so that the jig tray can perform the pressing operation smoothly. After the pressing operation is finished, the handling member 540 drives the jig tray to leave the pressing mold 600, thereby facilitating the transporting of the handling robot 300 again. The third supporting seat 530 and the carrying member 540 are used for respectively transporting the jig tray, so that the dislocation problem caused by excessive movement can be effectively avoided, and the smooth transportation process can be ensured.

Specifically, a carrying rail 545 is disposed in the pressing mold 600, and the carrying member 540 is movably disposed on the carrying rail 545. The carrying rail 545 is provided with a hollow space, and the material pressing die 600 can pass through the hollow space and press materials on the jig tray.

It is envisioned that the third support 530 may also drive the jig tray with failed pressing through the working position 550 and separate from the pressing mold 600 from a direction different from the direction of the carrying member 540, so as to facilitate recycling the jig tray with failed pressing. The specific embodiments can be adjusted according to actual needs, and are not limited herein.

In some embodiments, referring to fig. 2, a cooling mechanism 900 is disposed beside the blanking table 800, and the cooling mechanism 900 can cool the jig tray. The cooling mechanism 900 can cool the jig tray after the pressing operation is finished, so that the subsequent operation of the jig tray is facilitated, and the damage to workers or subsequent machines caused by overhigh heat in the subsequent operation is avoided.

Specifically, the cooling mechanism 900 includes a plurality of heat dissipation fans 950 disposed beside the blanking table 800, and the heat dissipation fans 950 directly blow air to the jig tray, and achieve the effect of heat dissipation and cooling.

It is envisioned that the jig tray may be driven by a worker manually through a tool or by hand directly from the blanking table 800 to the heat dissipation fan 950, or may be conveyed by various conveying mechanisms, and the specific embodiment may be adjusted accordingly according to actual needs, which is not limited herein.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present invention.

Claims

1. The utility model provides a well mould material loading machine which characterized in that includes:

a loading table (100) and a discharging table (800);

the feeding mechanism (200) can move close to or far away from the feeding table (100) and drive the jig plate to move;

the powder filling mechanism (400) can fill powder into the jig tray;

the material pressing die (600) can compact and shape materials in the jig tray;

the conveying mechanical arm (300), feed mechanism (200) fill out powder mechanism (400) press material mould (600) with unloading platform (800) encircle conveying mechanical arm (300) distributes, conveying mechanical arm (300) can drive tool dish of feed mechanism (200) department moves to in proper order fill out powder mechanism (400) press material mould (600) with unloading platform (800).

2. The intermediate die feeder of claim 1, wherein:

the feeding mechanism (200) comprises a first supporting seat (210), the first supporting seat (210) is connected with a displacement assembly (230), and the displacement assembly (230) can drive the first supporting seat (210) to move close to or far away from the feeding table (100).

3. The intermediate die feeder of claim 2, wherein:

the side of material loading platform (100) is provided with protection piece (270), transport arm (300) with material loading platform (100) are located respectively the both sides of protection piece (270), first supporting seat (210) can drive the tool dish motion and pass protection piece (270).

4. The intermediate die feeder of claim 1, wherein:

the powder filling mechanism (400) comprises a second supporting seat (420) and a powder chamber (430), the carrying mechanical arm (300) can drive the jig tray to move to the second supporting seat (420), and the second supporting seat (420) can drive the jig tray to move to the powder chamber (430); the powder chamber (430) is provided with a powder filling punch (410), and the powder filling punch (410) can move to be close to the powder chamber (430) and punch powder in the powder chamber (430) to the jig tray.

5. The intermediate die feeder of claim 4, wherein:

the bottom of the powder chamber (430) is provided with a plurality of powder falling holes, and the second bearing bracket (420) can drive the jig plate to move to the lower part of the powder chamber (430); the powder filling punch head (410) is connected with a powder filling driving piece (415), and the powder filling driving piece (415) can drive the powder filling punch head (410) to pass through the powder falling hole and push powder to the jig disc.

6. The intermediate die feeder of claim 4, wherein:

a powder bin (440) is arranged at the powder chamber (430), the powder bin (440) is connected with a displacement driving piece (450), and the powder bin (440) is provided with a powder outlet facing the bottom of the powder chamber (430); the displacement driving piece (450) can drive the powder bin (440) to move and enable the powder outlet to reciprocate in the powder bin (440).

7. The intermediate die feeder of claim 6, wherein:

the displacement driving piece (450) is connected with a turnover driving piece (470), and the turnover driving piece (470) is connected with the powder bin (440) and can drive the powder bin to turn; the powder bin (440) can be turned over until the powder outlet is mutually attached to the bottom wall of the powder bin (440).

8. The intermediate die feeder of claim 1, wherein:

the material pressing die (600) is provided with a preheating piece (500), and the carrying mechanical arm (300) can drive materials to move to the preheating piece (500) and perform preheating operation.

9. The intermediate die feeder of claim 8, wherein:

a working position (550) is arranged in the material pressing die (600), a third supporting seat (530) is arranged at the side of the material pressing die (600), and the third supporting seat (530) moves back and forth between the preheating piece (500) and the material pressing die (600); the material pressing die (600) is internally provided with a carrying piece (540), the carrying piece (540) moves back and forth between the outside of the material pressing die (600) and the working position (550), and the carrying mechanical arm (300) can move to be close to the carrying piece (540) after the material pressing die (600) is moved out.

10. The intermediate die feeder of claim 1, wherein:

the side of unloading platform (800) is provided with cooling mechanism (900), cooling mechanism (900) can cool down the tool dish.