CN115229528A - Chamfering device is used in production of manganese zinc ferrite magnetic core - Google Patents

Abstract

The invention relates to the technical field of chamfering devices, in particular to a chamfering device for producing a manganese-zinc ferrite magnetic core. According to the invention, the two first extension springs are arranged, the manganese-zinc ferrite magnetic core is clamped between the two positioning plates through the two first extension springs and is used for fixing the position of the manganese-zinc ferrite magnetic core, the stability of the manganese-zinc ferrite magnetic core during processing is improved, and meanwhile, the overturning stepping motor drives the manganese-zinc ferrite magnetic core to rotate, so that the unprocessed side edge of the manganese-zinc ferrite magnetic core is conveniently overturned upwards, and the chamfering processing operation of the manganese-zinc ferrite magnetic core is convenient.

Description

Chamfering device is used in production of manganese zinc ferrite magnetic core

Technical Field

The invention relates to the technical field of chamfering devices, in particular to a chamfering device for producing a manganese-zinc ferrite magnetic core.

Background

In the prior art, for example, a magnetic core chamfering machine applied to an annular magnetic core with the patent number "CN 201610410392.8" performs chamfering operation on the two end sides of the magnetic core through two chamfering devices and a 180-degree turnover mechanism, the two chamfering devices in the patent are used for chamfering the two end sides of the magnetic core in sequence, the 180-degree turnover mechanism turns over the magnetic core after primary chamfering, and one end which is not chamfered corresponds to the second chamfering device, so that the purchase and maintenance cost of equipment can be increased;

in addition, in the prior art, the manganese-zinc-ferrite core has not only a ring shape but also a rectangular or special-shaped manganese-zinc-ferrite core, and when the rectangular or special-shaped manganese-zinc-ferrite core is chamfered, the technology in the above patent cannot perform the chamfering operation.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a chamfering device for producing a manganese-zinc ferrite magnetic core.

In order to achieve the above purposes, the technical scheme adopted by the invention is as follows: a chamfering device for producing a manganese-zinc ferrite magnetic core comprises a base and a chamfering tool, wherein two second bearings are installed at the top of the base in a penetrating manner, inner rings of the two second bearings are respectively inserted with a first transmission shaft and a second transmission shaft in a tight fit manner, a second stepping motor is installed at the bottom end of the second transmission shaft through a coupler, the second stepping motor is installed at the bottom of the base through a motor support, the surfaces of the first transmission shaft and the second transmission shaft are respectively and fixedly provided with a driven gear and a driving gear, the driven gear is meshed with the driving gear, one side of the driving gear is provided with a first locking mechanism, the top end of the first transmission shaft is provided with a circular plate through a screw, the top end of the circular plate is provided with a horizontal movement linear motor through a screw, the movable end of the horizontal movement linear motor is connected with a bottom plate, the top of the bottom plate is provided with three limit blocks arranged in an equidistance manner through screws, a plurality of the top ends of the limit blocks are provided with a first support plate through screws, the top end of the first support plate is provided with a first mounting plate through a screw, two adjacent limit blocks are installed between the two elongated sliding blocks, one end of each sliding block is in a corresponding to the second elongated spring, and the end of the second mounting plate is in a corresponding to the end of the second elongated spring, and the second elongated spring, two the equal tight fit of inner circle of first bearing is pegged graft and is had the fixed axle, two the locating plate is all installed through the screw to the one end of fixed axle, one of them the other end of fixed axle has upset step motor through the coupling joint, upset step motor passes through the motor support mounting in the side of first mounting panel, two be equipped with the second mechanism of locking a position between rectangular sliding block and the bottom plate, the one end of base is equipped with adjustable chamfer mechanism.

Preferably, rubber pads are bonded on the side surfaces corresponding to the positions between the two positioning plates.

Preferably, the bottom of the bottom plate is provided with a plurality of supporting blocks through screws, at least two supporting blocks are arranged symmetrically, and the height of each supporting block is greater than that of the second stepping motor.

Preferably, the first locking mechanism comprises an electric cylinder, the electric cylinder is installed at the top of the base through a screw, a push block is installed at the movable end of the electric cylinder through a screw, a plurality of first tooth blocks are installed on the side face of the push block through a screw, and one ends of the first tooth blocks are respectively inserted into a plurality of tooth grooves of the driving gear.

Preferably, the second mechanism of being locked includes installed part, a plurality of tooth groove, first fixed plate and support piece, and is a plurality of the tooth groove is seted up respectively in the side of two rectangular sliding blocks, the both ends of installed part all have the second tooth piece through the mounting screw, the inside in tooth groove is laid in the second tooth piece matching, the side at the bottom plate is passed through to the one end of first fixed plate, the surface of first fixed plate is run through and is installed the slide bar, the bottom at the installed part is passed through to the one end of slide bar, the other end of slide bar has the second fixed plate through the mounting screw, the surperficial slip cover of slide bar is equipped with second extension spring, the surface at first fixed plate and second fixed plate is respectively installed through the screw in the both ends of second extension spring, sliding contact between slide bar and the first fixed plate, the bottom at the bottom of bottom plate is passed through to the one end of support piece, the other end of support piece extends to the below of second fixed plate, the other end of support piece has the metal block through the mounting screw, the electromagnet is passed through the bottom of second fixed plate and is installed the electromagnet through the screw, the position of electromagnet corresponds with the metal block.

Preferably, the installed part is concave, and the both ends of installed part correspond with the position of two rectangular sliding blocks respectively.

Preferably, at least twenty of the tooth-shaped grooves are arranged, and the tooth-shaped grooves are arranged at equal intervals.

Preferably, the minimum distance between the electromagnet and the metal block is smaller than the depth of the second tooth block inserted into the tooth-shaped groove.

Preferably, the adjustable chamfering mechanism comprises a vertical moving linear motor, the bottom of the vertical moving linear motor is installed at the top of the base through a screw, a second supporting plate is installed at the movable end of the vertical moving linear motor through a screw, a driving motor is installed at the top of the second supporting plate through a screw, the movable end of the driving motor penetrates through the surface of the second supporting plate and extends to the lower portion of the second supporting plate, a cutter clamp is installed at the movable end of the driving motor through a screw, one end of a chamfering cutter is fixed through clamping of the cutter clamp, and the chamfering cutter is located above the first supporting plate.

Preferably, the size of the driving gear is smaller than that of the driven gear.

Compared with the prior art, the invention has the following beneficial effects:

the second stepping motor is operated to drive the second transmission shaft to rotate, the second transmission shaft drives the first transmission shaft to rotate through the driving gear and the driven gear, the first transmission shaft drives the circular plate to rotate, the circular plate drives the manganese-zinc ferrite magnetic core to rotate in the horizontal direction, and the manganese-zinc ferrite magnetic core chamfering device is used for adjusting different sides to be in contact with a chamfering tool according to the shape of the manganese-zinc ferrite magnetic core and is convenient for adjusting the position of the manganese-zinc ferrite magnetic core;

according to the invention, the manganese-zinc ferrite magnetic core is driven to move in the horizontal direction by operating the horizontal movement linear motor, so that the manganese-zinc ferrite magnetic core is conveniently contacted with the chamfering tool, and the chamfering tool is conveniently used for chamfering the side edge of the manganese-zinc ferrite magnetic core;

according to the invention, the two first extension springs are arranged, the manganese-zinc ferrite magnetic core is clamped between the two positioning plates through the two first extension springs and is used for fixing the position of the manganese-zinc ferrite magnetic core, the stability of the manganese-zinc ferrite magnetic core during processing is improved, and meanwhile, the overturning stepping motor drives the manganese-zinc ferrite magnetic core to rotate, so that the unprocessed side edge of the manganese-zinc ferrite magnetic core is conveniently overturned upwards, and the chamfering processing operation of the manganese-zinc ferrite magnetic core is convenient.

Drawings

FIG. 1 is an isometric view of a chamfering apparatus for the production of a manganese-zinc-ferrite core of the present invention;

FIG. 2 is a schematic view of a connection structure of a horizontal movement linear motor, a bottom plate and a support plate of the chamfering device for producing a manganese-zinc ferrite core of the present invention;

FIG. 3 is a schematic view of a connecting structure of a limiting block, a long sliding block and a second mounting plate of the chamfering device for producing a manganese-zinc ferrite core of the present invention;

FIG. 4 is a schematic view of a connection structure of a bottom plate, a second stepping motor, a first transmission shaft and a second transmission shaft of the chamfering device for producing a manganese-zinc ferrite core of the present invention;

FIG. 5 is a schematic view of a connection structure of a driving gear and a driven gear of the chamfering device for producing a manganese-zinc-ferrite magnetic core according to the present invention;

FIG. 6 is a schematic view of the connection structure of the driving motor, the tool holder and the chamfering tool of the chamfering device for producing manganese-zinc ferrite magnetic cores of the present invention;

FIG. 7 is a schematic view of a connection structure of a second locking mechanism and a bottom plate of the chamfering device for producing the Mn-Zn ferrite core according to the present invention;

FIG. 8 is a schematic view of the connection structure of the electromagnet and the metal block of the chamfering device for producing a manganese-zinc-ferrite core according to the present invention;

FIG. 9 is a schematic view of a connection structure of a first locking mechanism of the chamfering device for producing a manganese-zinc-ferrite core of the present invention.

In the figure: the chamfering machine comprises a driving motor 1, a chamfering tool 2, a first mounting plate 3, a horizontal moving linear motor 4, a turnover stepping motor 5, a circular plate 6, a driving gear 7, a pushing block 8, an electric cylinder 9, a second stepping motor 10, a base 11, a supporting block 12, a limiting block 13, a first supporting plate 14, a bottom plate 15, a long sliding block 16, a rubber pad 17, a positioning plate 18, a second mounting plate 19, a vertical moving linear motor 20, a second supporting plate 21, a fixing shaft 22, a first bearing 23, a first tooth block 24, a tooth-shaped groove 25, a mounting piece 26, a baffle plate 27, a second tooth block 28, a first tension spring 29, a first transmission shaft 30, a second bearing 31, a second transmission shaft 32, a driven gear 33, a tool clamp 34, an electromagnet 35, a first fixing plate 36, a second tension spring 37, a supporting piece 38, a metal block 39, a second fixing plate 40 and a sliding rod 41.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

The chamfering device for producing the manganese-zinc-ferrite magnetic core shown in fig. 1-9 comprises a base 11 and a chamfering tool 2, wherein a plurality of supporting blocks 12 are arranged at the bottom of a bottom plate 15 through screws, at least two of the supporting blocks 12 are symmetrically arranged, and the height of each supporting block 12 is greater than that of a second stepping motor 10; the second stepping motor 10 is conveniently arranged below the bottom plate 15, and the plurality of supporting blocks 12 also play a role of supporting the device, so that the stability of the device on the ground is improved.

Two second bearings 31 are installed through the top of base 11, the inner circle of two second bearings 31 is tight-fitting respectively and is pegged graft and is had first transmission shaft 30 and second transmission shaft 32, second step motor 10 is installed through the shaft coupling in the bottom of second transmission shaft 32, second step motor 10 passes through the motor support and installs the bottom at base 11, fixed cover is equipped with driven gear 33 and driving gear 7 respectively on the surface of first transmission shaft 30 and second transmission shaft 32, driven gear 33 and driving gear 7 mesh, the size of driving gear 7 is less than the size of driven gear 33, when adjusting manganese zinc ferrite core's horizontal dimension, earlier pass through electric work with second step motor 10, second step motor 10 drives driving gear 7 through second transmission shaft 32 and rotates, driving gear 7 drives driven gear 33 and rotates, driven gear 33 drives first transmission shaft 30 and rotates, first transmission shaft 30 drives plectane 6 and rotates, and then make things convenient for the side of manganese zinc ferrite core to adjust in the horizontal direction and correspond with chamfering tool 2's position.

One side of driving gear 7 is equipped with first locking mechanism, first locking mechanism includes electronic jar 9, electronic jar 9 passes through the mounting screw at the top of base 11, electronic jar 9 expansion end has ejector pad 8 through the mounting screw, a plurality of first tooth pieces 24 are installed through the mounting screw in the side of ejector pad 8, a plurality of one end of first tooth piece 24 is pegged graft respectively in a plurality of tooth's socket of driving gear 7, behind the manganese zinc ferrite magnetic core adjusting position on the horizontal direction, still need to operate electronic jar 9 circular telegram work, electronic jar 9 expansion end promotes ejector pad 8, ejector pad 8 promotes a plurality of first tooth pieces 24 and removes the inside to the a plurality of tooth's socket of driving gear 7, a position for with driving gear 7 is spacing, the stability of driving gear 7 has been promoted, and then promote the stability of manganese zinc ferrite magnetic core position.

A circular plate 6 is mounted at the top end of a first transmission shaft 30 through a screw, a horizontal moving linear motor 4 is mounted at the top of the circular plate 6 through a screw, a bottom plate 15 is connected at the movable end of the horizontal moving linear motor 4, three limit blocks 13 which are arranged at equal intervals are mounted at the top of the bottom plate 15 through screws, a first support plate 14 is mounted between the tops of the limit blocks 13 through screws, a first mounting plate 3 is mounted at the top of the first support plate 14 through screws, a long sliding block 16 is slidably placed between two adjacent limit blocks 13, one end of each of the two long sliding blocks 16 extends to one side of the bottom plate 15, a first extension spring 29 is mounted at the other end of each of the two long sliding blocks 16 through screws, a baffle 27 is mounted between one ends of the two first extension springs 29 through screws, the side surface of the baffle 27 is respectively contacted with the end parts of the three limit blocks 13, a second mounting plate 19 is mounted between one ends of the two long sliding blocks 16 through screws, the positions of the second mounting plate 19 and the first mounting plate 3 correspond to each other, the top ends of the second mounting plate 19 and the first mounting plate 3 are respectively provided with a first bearing 23 in a penetrating way, the inner rings of the two first bearings 23 are respectively inserted with a fixed shaft 22 in a tight fit way, one end of each of the two fixed shafts 22 is provided with a positioning plate 18 through a screw, the other end of one fixed shaft 22 is connected with a turnover stepping motor 5 through a coupling, the turnover stepping motor 5 is arranged on the side surface of the first mounting plate 3 through a motor support, the second mounting plate 19 is pulled firstly when the position of the manganese-zinc ferrite magnetic core is fixed, the second mounting plate 19 pulls the two strip sliding blocks 16 to slide between the bottom plate 15 and the first supporting plate 14, meanwhile, the two strip sliding blocks 16 also slide along the side surfaces of the three limiting blocks 13, and the stability of the two strip sliding blocks 16 in moving is improved, the two strip sliding blocks 16 are forced to pull the two first extension springs 29, the baffle 27 is pulled while the lengths of the first extension springs 29 are extended, the side surfaces of the baffle 27 are blocked by the three limiting blocks 13, so that the manganese-zinc-ferrite magnetic cores are placed at the positions of the two positioning plates 18, the acting force of the second mounting plate 19 is cancelled, the two first extension springs 29 pull the second mounting plate 19 through the self reaction force, the second mounting plate 19 moves in the reverse direction after being forced, the second mounting plate 19 drives the positioning plate 18 to push the manganese-zinc-ferrite magnetic cores, the side surfaces of the other ends of the manganese-zinc-ferrite magnetic cores are contacted with the other positioning plate 18 after being forced, and the positions of the manganese-zinc-ferrite magnetic cores are fixed through the acting forces of the two first extension springs 29; after manganese zinc ferrite magnetic core top side chamfer is accomplished, can operate upset step motor 5 circular telegram work, upset step motor 5 drives fixed axle 22 at the internal rotation of primary shaft bearing 23, and then conveniently drives locating plate 18 synchronous rotation, make two locating plates 18 drive manganese zinc ferrite magnetic core upset position, promote the convenience of manganese zinc ferrite magnetic core position upset, after manganese zinc ferrite magnetic core upset is accomplished, the rigidity after manganese zinc ferrite magnetic core upset is accomplished through the locking force of upset step motor 5 self.

The side that the position corresponds between two locating plates 18 all bonds there is rubber pad 17, and rubber pad 17 is used for increasing the frictional force of locating plate 18 and the contact of manganese zinc ferrite magnetic core side, and then promotes the stability of manganese zinc ferrite magnetic core by the centre gripping of two locating plates 18, has further promoted the stability of manganese zinc ferrite magnetic core in the course of working.

A second locking mechanism is arranged between the two long sliding blocks 16 and the bottom plate 15, the second locking mechanism comprises a mounting piece 26, a plurality of tooth-shaped grooves 25, a first fixing plate 36 and a supporting piece 38, the plurality of tooth-shaped grooves 25 are respectively arranged on the side surfaces of the two long sliding blocks 16, the two ends of the mounting piece 26 are respectively provided with a second tooth block 28 through screws, the second tooth block 28 is arranged inside the tooth-shaped grooves 25 in a matching manner, one end of the first fixing plate 36 is arranged on the side surface of the bottom plate 15 through screws, the surface of the first fixing plate 36 is provided with a sliding rod 41 in a penetrating manner, one end of the sliding rod 41 is arranged at the bottom of the mounting piece 26 through screws, the other end of the sliding rod 41 is provided with a second fixing plate 40 through screws, the surface of the sliding rod 41 is slidably sleeved with a second extension spring 37, the two ends of the second extension spring 37 are respectively arranged on the surfaces of the first fixing plate 36 and the second fixing plate 40 through screws, one end of the supporting piece 38 is arranged at the bottom of the bottom plate 15 through screws, the corresponding electromagnet blocks 35 of the second fixing plate 40 are provided with metal blocks 39, and electromagnets 35; the mounting piece 26 is concave, and two ends of the mounting piece 26 respectively correspond to the positions of the two long sliding blocks 16; at least twenty tooth-shaped grooves 25 are arranged, and the tooth-shaped grooves 25 are arranged at equal intervals; the minimum distance between the electromagnet 35 and the metal block 39 is smaller than the depth of the second tooth block 28 inserted into the tooth-shaped groove 25; before the two long sliding blocks 16 move, the electromagnet 35 needs to be electrified to work, after the electromagnet 35 is electrified, magnetic force is generated to adsorb the metal block 39, and because the position of the metal block 39 is fixed, the electromagnet 35 moves towards the metal block 39, meanwhile, the electromagnet 35 drives the sliding rod 41 to move, the sliding rod 41 drives the mounting part 26 to move, the mounting part 26 drives the second tooth block 28 to move out of the tooth-shaped groove 25, and the second extension spring 37 is elongated along with the movement of the second fixing plate 40, so that the two long sliding blocks 16 can be conveniently pulled; the position of the manganese-zinc ferrite core is fixed by the two positioning plates 18, the electromagnet 35 is only required to be powered off, the magnetic force of the electromagnet 35 at the moment disappears, the second stretching spring 37 reversely pulls the second fixing plate 40 through self acting force, the second fixing plate 40 is pulled to reset by the sliding rod 41 after being stressed, meanwhile, the sliding rod 41 drives the second gear block 28 to be inserted into the tooth-shaped groove 25, the position of the two strip sliding blocks 16 is fixed, and the stability of the two positioning plates clamped on the side faces of the two ends of the manganese-zinc ferrite core is further improved.

An adjustable chamfering mechanism is arranged at one end of the base 11 and comprises a vertical moving linear motor 20, the bottom end of the vertical moving linear motor 20 is installed at the top of the base 11 through a screw, a second supporting plate 21 is installed at the movable end of the vertical moving linear motor 20 through a screw, a driving motor 1 is installed at the top of the second supporting plate 21 through a screw, the movable end of the driving motor 1 penetrates through the surface of the second supporting plate 21 and extends to the lower side of the second supporting plate 21, a tool clamp 34 is installed at the movable end of the driving motor 1 through a screw, one end of a chamfering tool 2 is clamped and fixed through the tool clamp 34, and the chamfering tool 2 is located above the first supporting plate 14; when the side chamfer with manganese zinc ferrite magnetic core, earlier drive motor 1 circular telegram work, drive cutter holder 34 after drive motor 1 circular telegram rotates, cutter holder 34 drives chamfering tool 2 and rotates in step, highly operate linear electric motor 20 between last according to manganese zinc ferrite magnetic core side and the chamfering tool 2, the expansion end moves in vertical direction after linear electric motor 20 circular telegram, its expansion end drives second backup pad 21 and moves in vertical direction, and second backup pad 21 drives chamfering tool 2 and moves to and stops working behind the position that corresponds with manganese zinc ferrite magnetic core side level, and drive motor 1 continues to do work, it conveniently rotates the convenient side chamfer operation to manganese zinc ferrite magnetic core of drive motor 1 drive chamfering tool 2.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The chamfering device for the production of the manganese-zinc ferrite magnetic core comprises a base (11) and a chamfering tool (2), and is characterized in that two second bearings (31) are installed at the top of the base (11) in a penetrating manner, the inner rings of the second bearings (31) are respectively and tightly inserted with a first transmission shaft (30) and a second transmission shaft (32), a second stepping motor (10) is installed at the bottom end of the second transmission shaft (32) through a coupler, the second stepping motor (10) is installed at the bottom of the base (11) through a motor support, a driven gear (33) and a driving gear (7) are fixedly sleeved on the surfaces of the first transmission shaft (30) and the second transmission shaft (32) respectively, the driven gear (33) is meshed with the driving gear (7), a first locking mechanism is arranged on one side of the driving gear (7), a screw (6) is installed at the top end of the first transmission shaft (30) through screws, a horizontal movement linear motor (4) is installed at the top of the circular plate (6) through screws, a movable end of the horizontal movement linear motor (4) is connected with a bottom plate (15), a plurality of screws (13) are installed between the top ends of the circular plate (15), and a plurality of limit blocks (14) are installed through a plurality of limit block (13), a long sliding block (16) is placed between two adjacent limiting blocks (13) in a sliding manner, one end of each long sliding block (16) extends to one side of the bottom plate (15), a first extension spring (29) is installed at the other end of each long sliding block (16) through a screw, a baffle (27) is installed between one end of each first extension spring (29) through a screw, the side surfaces of the baffle plates (27) are respectively contacted with the end parts of the three limit blocks (13), a second mounting plate (19) is arranged between one ends of the two long sliding blocks (16) through screws, the second mounting plate (19) corresponds to the first mounting plate (3), first bearings (23) are installed at the top ends of the second installation plate (19) and the first installation plate (3) in a penetrating mode, fixed shafts (22) are inserted into inner rings of the two first bearings (23) in a tight fit mode, positioning plates (18) are installed at one ends of the two fixed shafts (22) through screws, the other end of one of the fixed shafts (22) is connected with a turnover stepping motor (5) through a coupler, upset step motor (5) are through motor support mounting in the side of first mounting panel (3), two be equipped with the second mechanism of locking a position between rectangular sliding block (16) and bottom plate (15), the one end of base (11) is equipped with adjustable chamfer mechanism.

2. The chamfering device for manganese-zinc-ferrite magnetic core production according to claim 1, wherein rubber pads (17) are bonded to the corresponding side surfaces between the two positioning plates (18).

3. The chamfering device for manganese-zinc-ferrite core production according to claim 1, wherein a plurality of support blocks (12) are installed at the bottom of the bottom plate (15) by screws, at least two of the support blocks (12) are provided and symmetrically arranged, and the height of the support blocks (12) is greater than that of the second stepping motor (10).

4. The chamfering device for producing the manganese-zinc-ferrite magnetic core according to claim 1, wherein the first locking mechanism comprises an electric cylinder (9), the electric cylinder (9) is installed at the top of the base (11) through a screw, a push block (8) is installed at the movable end of the electric cylinder (9) through a screw, a plurality of first tooth blocks (24) are installed on the side surface of the push block (8) through a screw, and one ends of the first tooth blocks (24) are respectively inserted into a plurality of tooth grooves of the driving gear (7).

5. The chamfering device for manganese-zinc-ferrite core production according to claim 1, wherein the second locking mechanism comprises a mounting member (26), a plurality of tooth-shaped grooves (25), a first fixing plate (36) and a support member (38), the plurality of tooth-shaped grooves (25) are respectively opened at the sides of the two elongated sliding blocks (16), both ends of the mounting member (26) are respectively provided with a second rack (28) by screws, the second rack (28) is fittingly placed inside the tooth-shaped grooves (25), one end of the first fixing plate (36) is mounted at the side of the base plate (15) by screws, the surface of the first fixing plate (36) is penetratingly provided with a sliding rod (41), one end of the sliding rod (41) is mounted at the bottom of the mounting member (26) by screws, the other end of the sliding rod (41) is provided with a second fixing plate (40) by screws, the surface of the sliding rod (41) is slidably sleeved with a second tension spring (37), both ends of the second tension spring (37) are respectively mounted at the surfaces of the first fixing plate (36) and the second fixing plate (40), one end of the sliding rod (41) is in contact with the support member (38), and one end of the second tension spring (37) extends to the bottom of the base plate (38), the other end of the supporting piece (38) is provided with a metal block (39) through a screw, the bottom of the second fixing plate (40) is provided with an electromagnet (35) through a screw, and the electromagnet (35) corresponds to the metal block (39) in position.

6. A chamfering device for manganese-zinc-ferrite core production according to claim 5, characterized in that said mounting piece (26) is concave in shape, the two ends of said mounting piece (26) corresponding to the position of the two elongated sliding blocks (16), respectively.

7. A chamfering device for manganese-zinc-ferrite core production according to claim 5, characterized in that said tooth-shaped grooves (25) are provided in at least twenty, said tooth-shaped grooves (25) being arranged equidistantly.

8. A chamfering device for manganese-zinc-ferrite core production according to claim 5, characterized in that the minimum distance dimension between the electromagnet (35) and the metal block (39) is smaller than the depth dimension of the second tooth block (28) inserted into the tooth-shaped groove (25).

9. The chamfering device for producing the manganese-zinc-ferrite magnetic core according to claim 1, wherein the adjustable chamfering mechanism comprises a vertically moving linear motor (20), the bottom end of the vertically moving linear motor (20) is mounted at the top of the base (11) through a screw, a second supporting plate (21) is mounted at the movable end of the vertically moving linear motor (20) through a screw, a driving motor (1) is mounted at the top of the second supporting plate (21) through a screw, the movable end of the driving motor (1) penetrates through the surface of the second supporting plate (21) and extends to the lower portion of the second supporting plate (21), a tool clamp (34) is mounted at the movable end of the driving motor (1) through a screw, one end of the chamfering tool (2) is clamped and fixed through the tool clamp (34), and the chamfering tool (2) is located above the first supporting plate (14).

10. The chamfering device for manganese-zinc-ferrite core production according to claim 1, wherein the size of the driving gear (7) is smaller than the size of the driven gear (33).

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