CN114571611B - Cutting device is used in production of foreign ferrite magnetic particle processing - Google Patents

Abstract

The invention belongs to the technical field of production of anisotropic ferrite magnetic particles, in particular to a cutting device for production and processing of the anisotropic ferrite magnetic particles, which comprises a fixed table; an inverted U-shaped frame is fixedly connected to the fixed table; the inverted U-shaped frame is fixedly connected with a hydraulic cylinder, the output end of the hydraulic cylinder is provided with a hydraulic rod, and the hydraulic rod penetrates through the inverted U-shaped frame and is fixedly connected with a lower pressing plate; a group of cutting plates are fixedly connected to the bottom end of the lower pressing plate, and are uniformly arranged; the fixed table is connected with a square frame in a sliding way through a first sliding groove; the top end of the square frame is provided with a group of cutting grooves; in order to solve when cutting the magnetic sheet that rolls and extend, often place to cut the processing, and to the cutting of magnetic stripe carry out the cutting processing through promoting the removal that the magnetic sheet carried out, but the magnetic sheet has certain compliance, promotes and easily produces the deformation, leads to the cutting inhomogeneous, and the efficiency of monolithic magnetic sheet cutting processing is lower, influences the problem to the production of magnetic stripe greatly.

Description

Cutting device is used in production of foreign ferrite magnetic particle processing

Technical Field

The invention belongs to the technical field of production of anisotropic ferrite magnetic particles, and particularly relates to a cutting device for production and processing of anisotropic ferrite magnetic particles.

Background

The magnetic particles of the anisotropic ferrite are subjected to a room-temperature particle banburying technology, so that the anisotropic magnetic particles suitable for the magnetic strips of the motor can be prepared, then the magnetic strips are manufactured by rolling and calendaring particle clusters, then the magnetic strips are cut into the magnetic strips, the surfaces of the magnetic strips are uniform, no bubbles exist, and the magnetic strips of the motor produced by the product have high magnetic property and good stability. The motor rotation speed is 10% higher than normal under 150V low voltage, and the rotation speed is controlled to be 2% in different voltage ranges from 150V to 250V.

In the prior art, when the rolling and extending magnetic sheets are cut, single sheets are often placed for cutting, and the magnetic sheets are cut by pushing the magnetic sheets to move, but the magnetic sheets have certain flexibility, the magnetic sheets are easy to deform due to pushing, so that the cutting is uneven, the efficiency of the cutting treatment of the single sheets is low, and the production of the magnetic sheets is greatly influenced.

Disclosure of Invention

In order to overcome the deficiencies of the prior art, at least one technical problem presented in the background art is solved.

The technical scheme adopted for solving the technical problems is as follows: the invention relates to a cutting device for manufacturing and processing anisotropic ferrite magnetic particles, which comprises a fixed table; an inverted U-shaped frame is fixedly connected to the fixed table; the inverted U-shaped frame is fixedly connected with a hydraulic cylinder, the output end of the hydraulic cylinder is provided with a hydraulic rod, and the hydraulic rod penetrates through the inverted U-shaped frame and is fixedly connected with a lower pressing plate; a group of cutting plates are fixedly connected to the bottom end of the lower pressing plate, and are uniformly arranged; the fixed table is connected with a square frame in a sliding way through a first sliding groove; the top end of the square frame is provided with a group of cutting grooves; in the prior art, when the rolling and extending magnetic sheets are cut, the single sheets are often placed for cutting, the magnetic sheets are cut by pushing the magnetic sheets to move, but the magnetic sheets have certain flexibility, the magnetic sheets are easy to deform, so that the cutting is uneven, and the efficiency of the cutting treatment of the single sheets of magnetic sheets is lower, so that the production efficiency of the magnetic sheets is greatly influenced.

Preferably, a first through groove is formed in the inner wall of one side of the square frame, and a placing groove is formed in the side wall of the other side of the square frame; the first through groove corresponds to the placing groove in position; a placing plate is connected to the inner wall of the first through groove in a sliding manner; a U-shaped handle is fixedly connected to the side wall of the placing plate; the fixed table is provided with a collecting groove; the placing plate is fixed through a clamping piece in the first through groove; during operation, for the convenience to the collection of the magnetic stripe after the cutting, be equipped with in the back shape frame and place the board, place the board and fix through the screens piece, place the board simultaneously and be one end and fix through the standing groove, then stack the magnetic sheet on the board of placing in the back shape frame, after the cutting, pull back the back shape frame through the U-shaped handle, square back shape frame is located the collecting vat directly over, then will remove the screens piece, continue to place the board through U-shaped handle pulling, then place the magnetic stripe after the cutting on the board and can get into the collecting vat in, and then accomplish the collection of placing the magnetic stripe, can avoid needing manual follow back shape frame to take out the magnetic stripe, practice thrift the collecting time to the magnetic stripe, convenient and fast, further accelerate the cutting efficiency to the magnetic stripe.

Preferably, the clamping piece comprises a first groove; a baffle is fixedly connected to the top end of the fixed table; a first trapezoid block is fixedly connected to the baffle; a first groove is formed in the position of the rectangular frame relative to the first trapezoid block; the bottom end of the first groove is fixedly connected with a second trapezoid block through a spring; the top end of the second trapezoid block is fixedly connected with a clamping plate, and the clamping plate extends into the first through groove; during operation, when drawing out the shape frame that returns through the U-shaped handle, first trapezoidal piece is in fixed state this moment, can promote the trapezoidal piece of second and move down, and the trapezoidal piece of second moves down can drive the screens board and moves down, and then releases the spacing removal to placing the board, then continue to stimulate the U-shaped handle, will place the board and stimulate, conveniently carry out the collection to the magnetic stripe, when spacing to placing the board simultaneously, fixed back shape frame earlier this moment, and the board is placed in direct promotion, then drives the screens board through the spring force of the trapezoidal piece of second and move up, and then carries out spacing processing to placing the board.

Preferably, the bottom end of the placing plate is provided with a limiting chute; the position of the limiting chute and the position of the clamping plate correspond to each other; during operation, be equipped with spacing spout in placing the board bottom, move down the back at the screens board, can get into in the spacing spout, when moving the board of placing through the U-shaped handle, can avoid directly placing the board and pull out the shape frame completely outside this moment through spacing of spacing spout, can effectively avoid appearing installing the condition of placing the board again.

Preferably, the bottom end of the lower pressing plate is provided with a second groove, and the second groove is arranged at a position between a pair of cutting sheets; the bottom of the second groove is fixedly connected with a pressing block through a spring; a first cavity is formed in the pressing block; the bottom of the second groove is fixedly connected with a guide pillar, and the guide pillar extends into the first cavity; during operation, move the board down and move down and cut the magnetic sheet through the cutting piece, the briquetting earlier contacts with the magnetic sheet at this moment, then the briquetting can be under the effect of spring to the magnetic sheet pressfitting fixed, then cut the magnetic sheet of fixed state through cutting skin, the magnetic sheet appears the displacement when can avoiding appearing cutting and influence cutting quality, and when the cutting piece cutting is dark more, the pressure force of briquetting just is stronger, further guarantee cutting quality, and guide pillar leads to the removal of briquetting simultaneously, avoid appearing the circumstances of skew.

Preferably, a group of arc-shaped grooves are formed in the side walls of the two sides of the pressing block; the bottom of the arc-shaped groove is fixedly connected with a vibration column through a spring; a first inclined plane is formed on the inner wall of the opening of the second groove; during operation, when the holding down plate is in the state of not pushing down, the vibrations post can laminate on the cutting piece under the effect of spring this moment, when the holding down plate moves down, the briquetting can get into in the second recess under the effect of pressure this moment, the vibrations post can get into the arc wall under first inclined plane this moment, then get into in the second recess, after the cutting piece cuts the magnetic sheet, the holding down plate moves down this moment, the briquetting can remove under the spring force, then can come out from the second recess through the vibrations post in, can vibrate the processing to the cutting piece under the effect of spring, attaching the magnetic stripe on can effectively avoiding the cutting piece, also can clear up the impurity on the cutting piece effectively.

Preferably, a pair of arc plates are symmetrically distributed on the horizontal center line of the vibration column; a group of cleaning brushes are fixedly connected to the arc-shaped plate; during operation is equipped with the arc on the vibrations post, is equipped with the brush that cleans on the arc, stretches out in the second recess at the vibrations post, cleans the brush and can contact each other with the cutting piece surface this moment, and then clear up the cutting piece surface, avoids attaching to have cutting impurity on the cutting piece, influences the cutting effect of follow-up cutting piece.

Preferably, the end part of the arc-shaped plate is hinged on the vibration column, and the hinge point is provided with a torsion spring; a first air bag is arranged between the arc-shaped plate and the vibration column; a second cavity is formed in the vibration column; a convex plate is arranged in the second cavity; the inner wall of the first cavity is fixedly connected with a magnetic plate through a spring, the magnetic plate is fixedly connected with a connecting rod, and the end part of the connecting rod extends into the second cavity and is fixedly connected with a convex plate; the convex plate protrudes outwards towards the first cavity; a second air bag is fixedly connected between the concave surface in the convex plate and the inner wall of the second cavity; the first air bag and the second air bag are communicated with each other through a hose; the guide post is magnetic, and the magnetism between the guide post and the magnetic plate is attracted; when the device works, in order to prevent the movement of the arc plate from influencing the shrinkage of the vibration column into the arc groove, the magnetism of the guide column is utilized, when the pressing block enters the second groove, the guide column attracts the magnetic layer to move at the moment, and then drives the convex plate to move in the second cavity, and further pushes the vibration column to move towards the bottom of the arc groove, meanwhile, the extrusion of the second air bag is relieved, the first air bag is shrunk, and at the moment, the arc plate is driven to drive the cleaning brush to shrink, so that the cleaning brush enters the arc groove; simultaneously when the briquetting shifts out in the second recess, the magnetic layer is desorbed this moment, and the vibrations post is released spacingly, shakes the post to the cutting piece, and convex plate extrusion second gasbag this moment, second gasbag receive extrusion gas to get into in the first gasbag through the hose, and first gasbag inflation, and then drive the arc and expand, and the messenger cleans the brush and pastes tight cutting piece, and the reinforcing cleans the brush and cleans the effect to the cutting piece.

Preferably, a group of vibration balls are fixedly connected on the outer convex surface of the convex plate; during operation, the lug is when receiving the adsorption affinity of magnetic layer and remove, and the lug can collide each other with the second cavity inner wall earlier this moment, and then wholly shakes the processing to the vibrations post through the vibrations ball, and then can clear up the brush, and after the vibrations ball laminating second cavity inner wall, can pull the vibrations post wholly to the arc groove tank bottom removal.

Preferably, a group of rubber rings are fixedly connected on the outer side wall of the U-shaped handle; during operation is equipped with a set of rubber ring on the U-shaped handle, utilizes the protection of rubber ring to the U-shaped handle, can further protect the hand to holding of U-shaped handle, also avoids appearing the condition of injury palm simultaneously.

The beneficial effects of the invention are as follows:

1. according to the cutting device for producing and processing the anisotropic ferrite magnetic particles, the uniformly distributed cutting pieces are used for carrying out one-time cutting forming, the cutting grooves are arranged, the cutting pieces can be used for completely cutting off the stacked magnetic sheets, the situation of cutting off and connecting can not occur, the stacked magnetic sheets are used for carrying out one-time forming and cutting, the production efficiency of the magnetic strips can be greatly improved, the operation is simple and convenient, meanwhile, the safety of workers can be ensured by utilizing the back and forth movement of the square frame, and the accidental risk is reduced.

2. According to the cutting device for producing and processing the anisotropic ferrite magnetic particles, the uniformly distributed cutting pieces are used for carrying out one-time cutting forming, the cutting grooves are arranged, the cutting pieces can be used for completely cutting off the stacked magnetic sheets, the situation of cutting off and connecting can not occur, the stacked magnetic sheets are used for carrying out one-time forming and cutting, the production efficiency of the magnetic strips can be greatly improved, the operation is simple and convenient, meanwhile, the safety of workers can be ensured by utilizing the back and forth movement of the square frame, and the accidental risk is reduced.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a front view of the present invention;

FIG. 2 is a side view of the lower platen;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is a top view of the fixture table;

FIG. 5 is a cross-sectional view taken at B-B of FIG. 4;

FIG. 6 is an enlarged view of a portion of FIG. 5 at C;

FIG. 7 is a perspective view of the U-shaped handle;

in the figure: 1. a fixed table; 11. an inverted U-shaped frame; 12. a hydraulic cylinder; 13. a lower pressing plate; 14. cutting the sheet; 15. cutting a groove; 16. a square frame; 2. a first through groove; 21. a placement groove; 22. placing a plate; 23. a U-shaped handle; 25. a collection tank; 3. a first groove; 31. a clamping plate; 32. a first trapezoidal block; 33. a second trapezoidal block; 34. a baffle; 35. limiting sliding grooves; 4. a second groove; 41. briquetting; 42. a first cavity; 43. a guide post; 44. an arc-shaped groove; 45. a vibration column; 46. a first inclined surface; 5. an arc-shaped plate; 51. cleaning a brush; 52. a first air bag; 53. a second air bag; 54. a second cavity; 55. a convex plate; 56. a connecting rod; 57. a magnetic plate; 58. a vibrating ball; 59. a rubber ring.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

Example 1

As shown in fig. 1, a cutting device for manufacturing and processing anisotropic ferrite magnetic particles according to an embodiment of the present invention includes a fixing table 1; an inverted U-shaped frame 11 is fixedly connected to the fixed table 1; the inverted U-shaped frame 11 is fixedly connected with a hydraulic cylinder 12, the output end of the hydraulic cylinder 12 is provided with a hydraulic rod, and the hydraulic rod penetrates through the inverted U-shaped frame 11 and is fixedly connected with a lower pressing plate 13; a group of cutting plates 14 are fixedly connected to the bottom end of the lower pressing plate 13, and the group of cutting plates 14 are uniformly arranged; the fixed table 1 is connected with a square frame 16 in a sliding way through a first sliding chute; the top end of the square frame 16 is provided with a group of cutting grooves 15; in the prior art, when the rolling and extending magnetic sheets are cut, the single sheets are often placed for cutting, and the magnetic sheets are cut by pushing the magnetic sheets to move, but the magnetic sheets have certain flexibility, the magnetic sheets are easy to deform, so that the cutting is uneven, and the efficiency of the cutting treatment of the single sheets of magnetic sheets is lower, so that the production of the magnetic sheets is greatly influenced.

As shown in fig. 4 to 6, a first through groove 2 is formed on the inner wall of one side of the rectangular frame 16, and a placing groove 21 is formed on the side wall of the other side; the first through groove 2 corresponds to the placing groove 21 in position; the inner wall of the first through groove 2 is connected with a placing plate 22 in a sliding manner; a U-shaped handle 23 is fixedly connected to the side wall of the placing plate 22; the fixed table 1 is provided with a collecting groove 25; the placing plate 22 is fixed through a clamping piece in the first through groove 2; during operation, for the convenience to the collection of the magnetic stripe after cutting, be equipped with in returning shape frame 16 and place board 22, place board 22 and fix through the screens piece, place board 22 is that one end is fixed through standing groove 21 simultaneously, then stack the magnetic sheet on returning shape frame 16 places board 22, after the cutting, pull back returning shape frame 16 through U-shaped handle 23, square returning shape frame 16 is located collecting vat 25 directly over, then will remove the screens piece, continue to pull through U-shaped handle 23 and place board 22, then place the magnetic stripe after the cutting on the board 22 and can get into collecting vat 25 in, and then accomplish the collection of placing to the magnetic stripe, can avoid the manual magnetic stripe of taking out from returning shape frame 16, practice thrift the collecting time to the magnetic stripe, convenient and fast, further accelerate the cutting efficiency to the magnetic stripe.

The clamping piece comprises a first groove 3; a baffle 34 is fixedly connected to the top end of the fixed table 1; the baffle 34 is fixedly connected with a first trapezoid block 32; the position of the square frame 16 relative to the first trapezoid block 32 is provided with a first groove 3; the bottom end of the first groove 3 is fixedly connected with a second trapezoid block 33 through a spring; the top end of the second trapezoid block 33 is fixedly connected with a clamping plate 31, and the clamping plate 31 extends into the first through groove 2; during operation, when the back frame 16 is pulled out through the U-shaped handle 23, at this moment, the first trapezoid block 32 is in a fixed state, the second trapezoid block 33 is pushed to move downwards, the second trapezoid block 33 moves downwards and drives the clamping plate 31 to move downwards, and then the limiting movement of the placing plate 22 is relieved, then the U-shaped handle 23 is pulled continuously, the placing plate 22 is pulled, the collection of the magnetic stripes is facilitated, and meanwhile, when the placing plate 22 is limited, the back frame 16 is fixed at this moment, the placing plate 22 is directly pushed, then the clamping plate 31 is driven to move upwards through the spring force of the second trapezoid block 33, and then the placing plate 22 is subjected to limiting treatment.

A limiting chute 35 is formed at the bottom end of the placing plate 22; the position of the limit chute 35 and the position of the clamping plate 31 correspond to each other; during operation, be equipped with spacing spout 35 in placing board 22 bottom, move down the back at screens board 31, can get into in the spacing spout 35, when placing board 22 through U-shaped handle 23 comes, can avoid directly placing board 22 and pull out the shape frame 16 completely outside this moment through spacing of spacing spout 35, can effectively avoid appearing installing again and place the condition of board 22.

As shown in fig. 2 to 3, the bottom end of the lower pressing plate 13 is provided with a second groove 4, and the second groove 4 is arranged between a pair of cutting blades 14; the bottom of the second groove 4 is fixedly connected with a pressing block 41 through a spring; a first cavity 42 is formed in the pressing block 41; the bottom of the second groove 4 is fixedly connected with a guide post 43, and the guide post 43 extends into the first cavity 42; during operation, when the lower moving plate moves downwards to cut the magnetic sheet through the cutting sheet 14, the pressing block 41 is contacted with the magnetic sheet at this moment, then the pressing block 41 can press-fit and fix the magnetic sheet under the action of the spring, then the magnetic sheet in a fixed state is cut through the cutting skin, the influence of displacement of the magnetic sheet on the cutting quality can be avoided when the cutting occurs, and the pressing force of the pressing block 41 is stronger when the cutting sheet 14 cuts deeper, the cutting quality is further ensured, and meanwhile, the guide pillar 43 guides the movement of the pressing block 41, so that the condition of deviation is avoided.

A group of arc-shaped grooves 44 are formed in the side walls of the two sides of the pressing block 41; the bottom of the arc-shaped groove 44 is fixedly connected with a vibration column 45 through a spring; a first inclined plane 46 is formed on the inner wall of the opening of the second groove 4; when the work, when holding down plate 13 is in the state of not pushing down, vibrations post 45 can laminate on cutting piece 14 under the effect of spring this moment, when holding down plate 13 moves down, briquetting 41 can get into in the second recess 4 under the effect of pressure this moment, vibrations post 45 can get into arc wall 44 under first inclined plane 46 this moment, then get into in the second recess 4, after cutting piece 14 cuts the magnetic sheet, holding down plate 13 moves down this moment, briquetting 41 can move under the effect of spring force, then can come out from in the second recess 4 through vibrations post 45, can vibrate under the effect of spring handle cutting piece 14, can effectively avoid attaching the magnetic stripe on the cutting piece 14, also can effectively clear up the impurity on the cutting piece 14.

The vibration column 45 is provided with a pair of arc plates 5 symmetrically distributed about the horizontal center line of the vibration column 45; a group of cleaning brushes 51 are fixedly connected to the arc-shaped plate 5; during operation, be equipped with arc 5 on vibrations post 45, be equipped with on the arc 5 and clean brush 51, stretch out in the second recess 4 at vibrations post 45, clean brush 51 can contact each other with cutting piece 14 surface this moment, and then clear up cutting piece 14 surface, avoid attaching on the cutting piece 14 and have cutting impurity, influence the cutting effect of follow-up cutting piece 14.

The end part of the arc-shaped plate 5 is hinged on the vibration column 45, and the hinge point is provided with a torsion spring; a first air bag 52 is arranged between the arc-shaped plate 5 and the vibration column 45; a second cavity 54 is formed in the vibration column 45; a convex plate 55 is arranged in the second cavity 54; a magnetic plate 57 is fixedly connected to the inner wall of the first cavity 42 through a spring, a connecting rod 56 is fixedly connected to the magnetic plate 57, and the end part of the connecting rod 56 extends into the second cavity 54 and is fixedly connected to the convex plate 55; the convex plate 55 protrudes outwards towards the first cavity 42; a second air bag 53 is fixedly connected between the inner concave surface of the convex plate 55 and the inner wall of the second cavity 54; the first airbag 52 and the second airbag 53 are communicated with each other through a hose; the guide post 43 has magnetism, and the magnetism between the guide post 43 and the magnetic plate 57 is attracted; in order to avoid the influence of the movement of the arc plate 5 on the shrinkage of the vibration column 45 into the arc groove 44 during operation, when the pressing block 41 enters the second groove 4, the magnetism of the guide column 43 is utilized, and at the moment, the guide column 43 attracts the magnetic layer to move, so that the convex plate 55 is driven to move in the second cavity 54, the vibration column 45 is further pushed to move towards the bottom of the arc groove 44, meanwhile, the extrusion of the second air bag 53 is released, the first air bag 52 is shrunk, and at the moment, the arc plate 5 is driven to drive the cleaning brush 51 to shrink, so that the cleaning brush enters the arc groove 44; meanwhile, when the pressing block 41 moves out of the second groove 4, the magnetic layer is desorbed, the vibration column 45 releases limit, the vibration column 45 vibrates the cutting sheet 14, the convex plate 55 extrudes the second air bag 53, the second air bag 53 is extruded by extrusion gas, the extrusion gas enters the first air bag 52 through the hose, the first air bag 52 expands, the arc-shaped plate 5 is driven to be unfolded, the cleaning brush 51 is enabled to be tightly attached to the cutting sheet 14, and the cleaning effect of the cleaning brush 51 on the cutting sheet 14 is enhanced.

A group of vibration balls 58 are fixedly connected to the outer convex surface of the convex plate 55; during operation, when the lug moves under the adsorption force of the magnetic layer, the lug collides with the inner wall of the second cavity 54 at the moment, and then the vibration column 45 is integrally vibrated through the vibration ball 58, so that the cleaning brush 51 can be cleaned, and after the vibration ball 58 is attached to the inner wall of the second cavity 54, the vibration column 45 is pulled to integrally move to the bottom of the arc-shaped groove 44.

Example two

As shown in fig. 7, in comparative example one, another embodiment of the present invention is: a group of rubber rings 59 are fixedly connected to the outer side wall of the U-shaped handle 23; during operation, be equipped with a set of rubber ring 59 on the U-shaped handle 23, utilize the protection of rubber ring 59 to U-shaped handle 23, can further protect the hand to holding of U-shaped handle 23, also avoid appearing the condition of injury palm simultaneously.

Working principle: when the magnetic sheets subjected to rolling calendaring molding are required to be cut, the magnetic sheets are sequentially placed on the square frame 16 to be stacked, then the square frame 16 is pushed to enter the position right below the lower pressing plate 13, limiting treatment is carried out through the first sliding grooves, then the cutting sheets 14 which are uniformly distributed are subjected to one-time cutting molding, and through the arrangement of the cutting grooves 15, the cutting sheets 14 can be ensured to be completely cut off the stacked magnetic sheets, the situation of cutting and connecting can not occur, and the production efficiency of the magnetic strips can be greatly improved through one-time molding and cutting of the stacked magnetic sheets, the operation is simple and convenient, meanwhile, the safety of workers can be ensured by utilizing the back and forth movement of the square frame 16, and the accidental risk is reduced; in order to facilitate collection of the cut magnetic strips, a placement plate 22 is arranged in the square frame 16, the placement plate 22 is fixed through a clamping piece, one end of the placement plate 22 is fixed through a placement groove 21, then magnetic sheets are stacked on the placement plate 22 in the square frame 16, after cutting is finished, the square frame 16 is pulled back through a U-shaped handle 23 and is positioned right above a collecting groove 25, then the clamping piece is released, the placement plate 22 is pulled continuously through the U-shaped handle 23, then the cut magnetic strips on the placement plate 22 enter the collecting groove 25, further collection and placement of the magnetic strips are completed, the magnetic strips can be prevented from being taken out from the square frame 16 manually, collection time of the magnetic strips is saved, convenience and rapidness are realized, and cutting efficiency of the magnetic strips is further improved; when the U-shaped handle 23 is used for pulling out the back-shaped frame 16, the first trapezoid block 32 is in a fixed state, the second trapezoid block 33 is pushed to move downwards, the second trapezoid block 33 moves downwards to drive the clamping plate 31 to move downwards, further limit movement of the placing plate 22 is relieved, then the U-shaped handle 23 is pulled continuously, the placing plate 22 is pulled, collection of magnetic stripes is facilitated, meanwhile, when the placing plate 22 is limited, the back-shaped frame 16 is fixed at the moment, the placing plate 22 is directly pushed, then the clamping plate 31 is driven to move upwards by the spring force of the second trapezoid block 33, and further limit treatment is carried out on the placing plate 22; when the downward moving plate moves downwards to cut the magnetic sheet through the cutting sheet 14, the pressing block 41 is firstly contacted with the magnetic sheet, then the pressing block 41 can press and fix the magnetic sheet under the action of the spring, then the magnetic sheet in a fixed state is cut through the cutting skin, so that the influence of displacement of the magnetic sheet on the cutting quality can be avoided when the magnetic sheet is cut, the pressing force of the pressing block 41 is stronger when the cutting sheet 14 is cut deeper, the cutting quality is further ensured, and meanwhile, the guide pillar 43 guides the movement of the pressing block 41, and the condition of deviation is avoided; when the lower pressing plate 13 is in a non-pressing state, the vibration column 45 is attached to the cutting blade 14 under the action of the spring, when the lower pressing plate 13 moves downwards, the pressing block 41 enters the second groove 4 under the action of the pressure, the vibration column 45 enters the arc-shaped groove 44 under the action of the first inclined surface 46 and then enters the second groove 4, after the cutting blade 14 cuts the magnetic sheet, the lower pressing plate 13 moves downwards, the pressing block 41 moves under the action of the spring force, and then when the pressing block 41 comes out of the second groove 4 through the vibration column 45, the cutting blade 14 is subjected to vibration treatment under the action of the spring force, so that the attachment of a magnetic strip on the cutting blade 14 can be effectively avoided, and impurities on the cutting blade 14 can be effectively cleaned; in order to avoid that the movement of the arc plate 5 influences the shrinkage of the vibration column 45 into the arc groove 44, when the pressing block 41 enters the second groove 4, the magnetism of the guide column 43 is utilized, the guide column 43 attracts the magnetic layer to move at the moment, so that the convex plate 55 is driven to move in the second cavity 54, the vibration column 45 is further pushed to move towards the bottom of the arc groove 44, meanwhile, the extrusion of the second air bag 53 is released, the first air bag 52 is shrunk, the arc plate 5 is driven to drive the cleaning brush 51 to shrink at the moment, and the cleaning brush 51 is completed to enter the arc groove 44; meanwhile, when the pressing block 41 moves out of the second groove 4, the magnetic layer is desorbed, the vibration column 45 releases limit, the vibration column 45 vibrates the cutting sheet 14, the convex plate 55 extrudes the second air bag 53, the second air bag 53 is extruded by extrusion gas, the extrusion gas enters the first air bag 52 through the hose, the first air bag 52 expands, the arc-shaped plate 5 is driven to be unfolded, the cleaning brush 51 is enabled to be tightly attached to the cutting sheet 14, and the cleaning effect of the cleaning brush 51 on the cutting sheet 14 is enhanced.

The front, rear, left, right, up and down are all based on fig. 1 in the drawings of the specification, the face of the device facing the observer is defined as front, the left side of the observer is defined as left, and so on, according to the viewing angle of the person.

In the description of the present invention, it should be understood that the terms "center," "longitudinal," "lateral," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the scope of the present invention.

The foregoing has shown and described the basic principles, principal 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, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a cutting device is used in production and processing of foreign ferrite magnetic particle which characterized in that: comprises a fixed table (1); an inverted U-shaped frame (11) is fixedly connected to the fixed table (1); the inverted U-shaped frame (11) is fixedly connected with a hydraulic cylinder (12), the output end of the hydraulic cylinder (12) is provided with a hydraulic rod, and the hydraulic rod penetrates through the inverted U-shaped frame (11) and is fixedly connected with a lower pressing plate (13); a group of cutting pieces (14) are fixedly connected to the bottom end of the lower pressing plate (13), and the group of cutting pieces (14) are uniformly arranged; the fixed table (1) is connected with a square frame (16) in a sliding way through a first sliding groove; a group of cutting grooves (15) are formed in the top end of the square frame (16);

the bottom end of the lower pressing plate (13) is provided with a second groove (4), and the second groove (4) is arranged at a position between a pair of cutting sheets (14); the bottom of the second groove (4) is fixedly connected with a pressing block (41) through a spring; a first cavity (42) is formed in the pressing block (41); the bottom of the second groove (4) is fixedly connected with a guide pillar (43), and the guide pillar (43) extends into the first cavity (42);

a group of arc grooves (44) are formed in the side walls of the two sides of the pressing block (41); the bottom of the arc-shaped groove (44) is fixedly connected with a vibration column (45) through a spring; a first inclined plane (46) is formed on the inner wall of the opening of the second groove (4).

2. The cutting device for manufacturing and processing of anisotropic ferrite magnetic particles according to claim 1, wherein: a first through groove (2) is formed in the inner wall of one side of the square frame (16), and a placing groove (21) is formed in the side wall of the other side of the square frame; the first through groove (2) corresponds to the placing groove (21); a placing plate (22) is connected to the inner wall of the first through groove (2) in a sliding manner; a U-shaped handle (23) is fixedly connected to the side wall of the placing plate (22); the fixed table (1) is provided with a collecting groove (25); the placing plate (22) is fixed through a clamping piece in the first through groove (2).

3. The cutting device for manufacturing and processing of anisotropic ferrite magnetic particles according to claim 2, wherein: the clamping piece comprises a first groove (3); a baffle (34) is fixedly connected to the top end of the fixed table (1); a first trapezoid block (32) is fixedly connected to the baffle (34); a first groove (3) is formed in the position of the square frame (16) relative to the first trapezoid block (32); the bottom end of the first groove (3) is fixedly connected with a second trapezoid block (33) through a spring; the top end of the second trapezoid block (33) is fixedly connected with a clamping plate (31), and the clamping plate (31) stretches into the first through groove (2).

4. A cutting device for manufacturing and processing ferrite magnetic particles according to claim 3, wherein: a limiting chute (35) is formed in the bottom end of the placing plate (22); the position of the limit chute (35) and the position of the clamping plate (31) correspond to each other.

5. The cutting device for manufacturing and processing of anisotropic ferrite magnetic particles according to claim 1, wherein: a pair of arc plates (5) which are symmetrically distributed about the horizontal center line of the vibration column (45) are arranged on the vibration column (45); a group of cleaning brushes (51) are fixedly connected to the arc-shaped plate (5).

6. The cutting device for manufacturing and processing the anisotropic ferrite magnetic particles according to claim 5, wherein: the end part of the arc-shaped plate (5) is hinged on the vibration column (45), and the hinge point is provided with a torsion spring; a first air bag (52) is arranged between the arc-shaped plate (5) and the vibration column (45); a second cavity (54) is formed in the vibration column (45); a convex plate (55) is arranged in the second cavity (54); a magnetic plate (57) is fixedly connected to the inner wall of the first cavity (42) through a spring, a connecting rod (56) is fixedly connected to the magnetic plate (57), and the end part of the connecting rod (56) extends into the second cavity (54) and is fixedly connected to the convex plate (55); the convex plate (55) protrudes outwards towards the first cavity (42); a second air bag (53) is fixedly connected between the inner concave surface of the convex plate (55) and the inner wall of the second cavity (54); the first air bag (52) and the second air bag (53) are communicated with each other through a hose; the guide post (43) has magnetism, and magnetism is attracted between the guide post (43) and the magnetic plate (57).

7. The cutting device for manufacturing and processing the anisotropic ferrite magnetic particles according to claim 6, wherein: a group of vibration balls (58) are fixedly connected to the outer convex surface of the convex plate (55).

8. The cutting device for manufacturing and processing of anisotropic ferrite magnetic particles according to claim 2, wherein: a group of rubber rings (59) are fixedly connected to the outer side wall of the U-shaped handle (23).