CN218513312U - Magnetic core transfer device for powder forming machine - Google Patents

Abstract

The utility model relates to a magnetic core production technical field especially relates to a magnetic core transmission device for powder forming machine, including the carousel that is located powder forming machine one side, fixedly connected with rotation axis in the middle of the carousel, the rotation axis is by motor drive, fixedly connected with vertical axis one on the carousel, one rotation of vertical axis is connected with connecting rod one, connecting rod one keeps away from one end fixedly connected with vertical axis two of vertical axis, vertical axis two rotates and is connected with connecting rod two, connecting rod two keeps away from the one end of vertical axis two and rotates and be connected with clamping component, be equipped with the shifting chute in the middle of the connecting rod two, the track groove has been seted up to the shifting chute inner wall, be equipped with the bracing piece in the middle of the shifting chute, bracing piece top fixedly connected with supports the head, support and be equipped with the ring track on the disc outside the head, track groove and ring track sliding connection, the ring track is to the lopsidedness that is close to clamping component, the device has solved the magnetic core and has moved the wearing and tearing problem that output mechanism's in-process produced on the carousel from powder forming machine.

Description

Magnetic core transfer device for powder forming machine

Technical Field

The utility model relates to a magnetic core production technical field especially relates to a magnetic core transmission device for powder forming machine.

Background

The magnetic core is a main element in the inductor, in the production process, a powder forming machine is a common magnetic core production device, the powder forming machine conveys powder raw materials into a die for compression forming, then the compression-formed magnetic core is moved onto a conveying mechanism, and the conveying mechanism conveys a belt to a next process.

Chinese patent No. CN206564188U discloses a powder forming machine for an inductor magnetic core, in which a turntable is disposed above a circular bracket, the bracket is provided with a stop block, a rotating shaft is driven by a motor to rotate to drive the turntable to rotate, a pressed magnetic core is ejected out of the surface of the turntable and rotates along with the turntable, and the pressed magnetic core is stopped at the stop block and slides along the stop block to the direction of an output mechanism, so as to move the pressed magnetic core to the output mechanism.

In the prior art, when the magnetic core moves to the output mechanism from the turntable, the magnetic core and the rotating turntable move relatively to generate sliding friction, the magnetic core moves to the output mechanism along the stop block and also generates sliding friction, and the sliding friction can wear the surface of the magnetic core to influence the processing precision of a product.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

To the deficiency of the prior art, the utility model aims to provide a magnetic core transmission device for powder forming machine has solved the problem that exists among the prior art, and the device has solved the magnetic core and has removed the wearing and tearing problem that output mechanism's in-process produced on the carousel from powder forming machine.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a magnetic core transmission device for powder forming machine, including the carousel that is located powder forming machine one side, fixedly connected with rotation axis in the middle of the carousel, the rotation axis is by motor drive, fixedly connected with vertical axis one on the carousel, one end fixedly connected with vertical axis two that vertical axis one was kept away from to vertical axis one, vertical axis two rotates and is connected with connecting rod two, the one end that vertical axis two was kept away from to connecting rod two rotates and is connected with clamping part, be equipped with the shifting chute in the middle of the connecting rod two, the track groove has been seted up to the shifting chute inner wall, be equipped with the bracing piece in the middle of the shifting chute, bracing piece top fixedly connected with supports the head, be equipped with the ring track on supporting the head disc, track groove and ring track sliding connection, the track groove is to the lopsidedness that is close to clamping part.

Preferably, the clamping component comprises a connecting block, a fixed plate fixedly connected with the connecting block and two movable plates slidably connected to the fixed plate, and an electric telescopic rod is fixedly connected between the movable plates.

Preferably, a T-shaped groove is formed in one side of the fixed plate close to the moving plate, a T-shaped block is fixedly connected to one side of the moving plate close to the fixed plate, and the T-shaped block is slidably connected with the T-shaped groove.

Preferably, the T-shaped slot is horizontally disposed.

Preferably, the bottom of the connecting block is fixedly connected with a third vertical shaft, and the third vertical shaft is rotatably connected with one end, far away from the second vertical shaft, of the second connecting rod.

Preferably, a reversing mechanism is further arranged on one side of the clamping component.

Preferably, the reversing mechanism comprises a first connecting shaft fixedly connected to the top of the second vertical shaft and a second connecting shaft fixedly connected to the top of the connecting block, a driving gear is fixedly connected to the first connecting shaft, a driven gear is fixedly connected to the second connecting shaft, and a toothed belt is connected between the driving gear and the driven gear in a meshed mode.

(III) advantageous effects

1. The utility model provides a magnetic core transmission device for powder forming machine, the device passes through motor drive rotation axis clockwise rotation, it is rotatory clockwise to drive the carousel, the vertical axis drives connecting rod one on the carousel and rotates, it rotates to drive two connecting rods, two connecting rods rotate and drive the hold assembly and rotate, because two connecting rods rotate, the shifting chute produces with the support head and slides and rotate, make the track groove slide and rotate along the ring track, because the track groove sets up to a lopsidedness that is close to the hold assembly, therefore, along with the rotation of carousel, two connecting rods are raised, make the magnetic core of hold assembly centre gripping raised at the rotation in-process, make the magnetic core not produce sliding friction, avoid wearing and tearing.

2. The utility model provides a magnetic core transmission device for powder forming machine, the device is at two pivoted in-processes of connecting rod, two connecting rods and two vertical axis produce relative motion, two vertical axis are clockwise for two connecting rods promptly, drive connecting axle clockwise, drive driving gear clockwise, the driving gear passes through the cingulum and makes driven gear clockwise rotate, thereby make clamping part use three vertical axis to rotate clockwise for two connecting rods for the center, make the magnetic core can not take place to deflect because of the rotation of two connecting rods, be convenient for neatly carry next process.

Drawings

Fig. 1 is a schematic structural diagram of an overall plan view of the present invention.

Fig. 2 is a schematic structural view of the overall front view of the present invention.

Fig. 3 is a schematic structural diagram of the turntable of the present invention.

Fig. 4 is a schematic structural diagram of the first connecting rod of the present invention.

Fig. 5 is a schematic structural diagram of a second connecting rod according to the present invention.

Fig. 6 is a schematic structural view of a cross-sectional view of the connecting rod of the present invention.

Fig. 7 is a schematic structural view of the support rod of the present invention.

Fig. 8 is a schematic structural view of a top view of the clamping member of the present invention.

Fig. 9 is a schematic structural view of a front view of the holding member of the present invention.

Fig. 10 is a schematic structural view of a partially enlarged view of fig. 9 according to the present invention.

Fig. 11 is a schematic structural view of the reversing mechanism of the present invention.

In the figure: the device comprises a 1-rotating disc, a 2-rotating shaft, a 3-connecting rod I, a 4-connecting rod II, a 5-supporting rod, a 6-clamping component, a 7-reversing mechanism, an 8-powder forming machine, a 9-vertical shaft I, a 10-vertical shaft II, a 11-connecting shaft I, a 12-moving groove, a 13-track groove, a 14-supporting head, a 15-circular track, a 16-connecting block, a 17-fixing plate, a 18-moving plate, a 19-electric telescopic rod, a 20-vertical shaft III, a 21-connecting shaft II, a 22-T-shaped groove, a 23-T-shaped block, a 24-driving gear, a 25-driven gear, a 26-toothed belt and a 27-conveying belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to fig. 1 to 11 of the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a technical scheme: a magnetic core transfer device for a powder forming machine comprises a rotary table 1 positioned on one side of the powder forming machine 8, a rotary shaft 2 is fixedly connected in the middle of the rotary table 1, the rotary shaft 2 is driven by a motor, a vertical shaft I9 is fixedly connected on the rotary table 1, a connecting rod I3 is rotatably connected with the vertical shaft I9, one end of the connecting rod I3, far away from the vertical shaft I9, is fixedly connected with a vertical shaft II 10, the vertical shaft II 10 is rotatably connected with a connecting rod II 4, one end of the connecting rod II 4, far away from the vertical shaft II 10, is rotatably connected with a clamping part 6, a moving groove 12 is arranged in the middle of the connecting rod II 4, a track groove 13 is formed in the inner wall of the moving groove 12, a support rod 5 is arranged in the middle of the moving groove 12, a support head 14 is fixedly connected to the top of the support rod 5, a circular track 15 is arranged on the outer circular surface of the support head 14, the track groove 13 is slidably connected with the circular track 15, the track groove 13 inclines to one side close to the clamping part 6, when in use, the motor drives the rotating shaft 2 to rotate, the rotating disc 1 fixed at the top of the rotating shaft 2 is driven to rotate to the position shown in figure 1, at the moment, the magnetic core just rotates to the position of the clamping part 6 in figure 1 along with the rotation after the powder forming machine is pressed and formed, the clamping part 6 clamps the magnetic core, the motor drives the rotating shaft 2 to rotate clockwise, the rotating disc 1 is driven to rotate clockwise, the vertical shaft I9 on the rotating disc 1 drives the connecting rod I3 to rotate, the connecting rod II 4 rotates to drive the clamping part 6 to rotate, as the connecting rod II 4 rotates, the moving groove 12 and the supporting head 14 slide and rotate, the track groove 13 slides and rotates along the circular track 15, as the track groove 13 is obliquely arranged towards one side close to the clamping part 6, therefore, as the rotating disc 1 rotates, the connecting rod II 4 is lifted, so that the magnetic core clamped by the clamping part 6 is lifted in the rotating process, the magnetic core does not generate sliding friction, and abrasion is avoided.

The clamping component 6 comprises a connecting block 16, a fixing plate 17 fixedly connected with the connecting block 16 and two moving plates 18 connected to the fixing plate 17 in a sliding mode, an electric telescopic rod 19 is fixedly connected between the moving plates 18, a T-shaped groove 22 is formed in one side, close to the moving plate 18, of the fixing plate 17, the T-shaped groove 22 is horizontally arranged, a T-shaped block 23 is fixedly connected to one side, close to the fixing plate 17, of the moving plate 18, the T-shaped block 23 is connected with the T-shaped groove 22 in a sliding mode, when the magnetic core moves to one side of the fixing plate 17 in use, the magnetic core is located between the two moving plates 18, the electric telescopic rod 19 moves at the moment, and the T-shaped block 23 on the moving plate 18 slides towards the magnetic core along the T-shaped groove 22 to clamp the magnetic core.

The bottom of the connecting block 16 is fixedly connected with a vertical shaft III 20, the vertical shaft III 20 is rotatably connected with one end of the connecting rod II 4 far away from the vertical shaft II 10, one side of the clamping component 6 is also provided with a reversing mechanism 7, the reversing mechanism 7 comprises a connecting shaft I11 fixedly connected to the top of the vertical shaft II 10 and a connecting shaft II 21 fixedly connected to the top of the connecting block 16, a driving gear 24 is fixedly connected to the connecting shaft I11, a driven gear 25 is fixedly connected to the connecting shaft II 21, a toothed belt 26 is meshed and connected between the driving gear 24 and the driven gear 25, in use, after the magnetic core is clamped by the clamping component 6, the motor drives the rotating shaft 2 to rotate clockwise, the rotating disc 1 is driven to rotate clockwise, a first vertical shaft I9 on the rotating disc 1 drives a first connecting rod I3 to rotate, a second connecting rod II 4 rotates to drive the clamping component 6 to rotate, meanwhile, the second connecting rod II 4 and the vertical shaft II 10 generate relative movement, namely, the vertical shaft II 10 rotates clockwise relative to the connecting rod II 4, the first connecting shaft 11 rotates clockwise, the driving gear 24 rotates clockwise through the toothed belt 26 to enable the driven gear 25 to rotate clockwise, and accordingly, the clamping component 6 to enable the connecting rod II to be convenient to deflect relative to be conveyed to the magnetic core 4.

The working principle is as follows: the motor drives the rotating shaft 2 to rotate to drive the rotating disc 1 fixed at the top of the rotating shaft 2 to rotate to the position shown in figure 1, at the moment, the magnetic core just rotates to the position of the clamping part 6 in figure 1 along with the rotation after the magnetic core is pressed and formed by the powder forming machine, when the magnetic core moves to one side of the fixing plate 17, the magnetic core is positioned between the two moving plates 18, the electric telescopic rod 19 acts at the moment, the T-shaped block 23 on the moving plate 18 slides towards the magnetic core along the T-shaped groove 22 to clamp the magnetic core, the motor drives the rotating shaft 2 to rotate clockwise to drive the rotating disc 1, the vertical shaft I9 on the rotating disc 1 drives the connecting rod I3 to rotate and drives the connecting rod II 4 to rotate, the connecting rod II 4 rotates to drive the clamping part 6 to rotate, when the connecting rod II 4 rotates, the moving groove 12 and the supporting head 14 slide and rotate, so that the track groove 13 slides and rotates along the circular track 15, and because the track groove 13 is inclined to one side close to the clamping part 6, therefore, the connecting rod II 4 is lifted, so that the magnetic core clamped by the clamping part 6 is lifted in the rotating process of rotating process, and the magnetic core is not subjected to generate sliding friction, and the abrasion;

meanwhile, the second connecting rod 4 and the second vertical shaft 10 generate relative motion, that is, the second vertical shaft 10 rotates clockwise relative to the second connecting rod 4 to drive the first connecting shaft 11 to rotate clockwise and drive the driving gear 24 to rotate clockwise, and the driving gear 24 drives the driven gear 25 to rotate clockwise through the toothed belt 26, so that the clamping component 6 rotates clockwise relative to the second connecting rod 4 by taking the third vertical shaft 20 as a center;

when the turntable 1 rotates clockwise by 90 degrees, the track groove 13 slides reversely along the circular track 15, and the height of the clamping component 6 slowly descends;

when the turntable 1 rotates 180 degrees clockwise, the clamping part 6 for clamping the magnetic core rotates to the upper part of the conveying belt 27, the electric telescopic rod 19 acts, the T-shaped block 23 on the moving plate 18 slides reversely along the T-shaped groove 22 to loosen the magnetic core, and the magnetic core falls on the conveying belt 27 and is conveyed to the next processing procedure;

at this time, the motor drives the rotary shaft 2 to rotate in the reverse direction, and the gripping member 6 is rotated to the position shown in fig. 1 to transfer the next workpiece.

Claims (7)

1. The utility model provides a magnetic core transmission device for powder forming machine, is including carousel (1) that is located powder forming machine (8) one side, fixedly connected with rotation axis (2) in the middle of carousel (1), rotation axis (2) are by motor drive, fixedly connected with vertical axis (9) on carousel (1), vertical axis (9) are rotated and are connected with connecting rod (3), one end fixedly connected with vertical axis two (10) of vertical axis (9) are kept away from in connecting rod (3), vertical axis two (10) are rotated and are connected with connecting rod two (4), the one end rotation that vertical axis two (10) were kept away from in connecting rod two (4) is connected with clamping part (6), its characterized in that: be equipped with shifting chute (12) in the middle of two (4) connecting rods, track groove (13) have been seted up to shifting chute (12) inner wall, be equipped with bracing piece (5) in the middle of shifting chute (12), bracing piece (5) top fixedly connected with supports head (14), be equipped with ring track (15) on supporting head (14) the disc, track groove (13) and ring track (15) sliding connection, track groove (13) is to the lopsidedness that is close to clamping part (6).

2. The magnetic core transfer device for a powder molding machine according to claim 1, characterized in that: the clamping component (6) comprises a connecting block (16), a fixing plate (17) fixedly connected with the connecting block (16) and two moving plates (18) connected to the fixing plate (17) in a sliding mode, and an electric telescopic rod (19) is fixedly connected between the moving plates (18).

3. The magnetic core transfer device for a powder molding machine according to claim 2, characterized in that: the T-shaped groove (22) is formed in one side, close to the moving plate (18), of the fixed plate (17), a T-shaped block (23) is fixedly connected to one side, close to the fixed plate (17), of the moving plate (18), and the T-shaped block (23) is connected with the T-shaped groove (22) in a sliding mode.

4. The magnetic core transfer device for a powder molding machine according to claim 3, characterized in that: the T-shaped groove (22) is horizontally arranged.

5. The magnetic core transfer device for a powder molding machine according to claim 2, characterized in that: the bottom of the connecting block (16) is fixedly connected with a third vertical shaft (20), and the third vertical shaft (20) is rotatably connected with one end, far away from the second vertical shaft (10), of the second connecting rod (4).

6. The magnetic core transfer device for a powder molding machine according to claim 5, characterized in that: and a reversing mechanism (7) is further arranged on one side of the clamping component (6).

7. The magnetic core transfer device for a powder molding machine according to claim 6, characterized in that: reversing mechanism (7) are including fixed connection the connecting axle one (11) and the fixed connection at two (10) tops of vertical axis are in the connecting axle two (21) at connecting block (16) top, fixedly connected with driving gear (24) on connecting axle one (11), fixedly connected with driven gear (25) on connecting axle two (21), the meshing is connected with cingulum (26) between driving gear (24) and driven gear (25).

Images