CN117773722A - Automatic swing piece device of processing subassembly and magnetic material polishes - Google Patents

Abstract

The invention relates to the technical field of devices for grinding, and in particular relates to a grinding processing assembly and an automatic magnetic material arranging device, which comprise a grinding processing assembly, wherein one side of the grinding processing assembly is provided with a mechanical arm vision robot and a feeding frame, and the grinding processing assembly is used for grinding the upper surface, the lower surface, the left side and the right side of a cuboid sheet magnetic material; the mechanical arm vision robot is used for swinging the cuboid sheet-shaped magnetic material polished on the polishing processing assembly into the feeding frame; the placing component is arranged on one side of the II-section limiting groove body of the polishing processing component; a belt conveyor is arranged below the placement assembly, and a diffusion disc body is placed on the belt conveyor; the invention solves the problem that the existing polishing equipment cannot synchronously polish the upper, lower, left and right surfaces of the batched cuboid sheet-shaped magnetic materials.

Description

Automatic swing piece device of processing subassembly and magnetic material polishes

Technical Field

The invention relates to the technical field of devices for grinding, and simultaneously relates to the technical field of conveying devices, in particular to a grinding processing assembly and an automatic magnetic material arranging device.

Background

As shown in fig. 1, a rectangular sheet-shaped magnetic material currently sold in the market is shown, and the processing steps of the magnetic material are as follows in fig. 2: a, rough grinding processing of cuboid block-shaped magnetic materials; b, cutting the cuboid massive magnetic material into cuboid flaky magnetic materials; c, finely grinding the cuboid flaky magnetic material; d, automatically arranging the batched cuboid flaky magnetic materials and diffusing the cuboid flaky magnetic materials; in the fine grinding process, the upper and lower surfaces and the left and right side surfaces of the cuboid sheet magnetic material need to be thoroughly ground, wherein the upper and lower surfaces are respectively S1 and S2 in the figure 1, and the left and right side surfaces are S2 and S3 in the figure 1; the technology related to the grinding of magnetic materials is disclosed in Chinese patent library, for example, patent CN114434284B discloses a neodymium iron boron magnet grinding device which comprises a grinding wheel and a positioning mechanism, wherein the positioning mechanism comprises a first rotating shaft and a second rotating shaft which are respectively and rotatably arranged on a rack on two sides of the grinding wheel, a fixing piece is fixedly connected between the first rotating shaft and the second rotating shaft, and a plurality of matched main positioning components and auxiliary positioning components are respectively arranged on the first rotating shaft and the second rotating shaft; the frame is provided with a loading and unloading assembly matched with the fixed cylinder.

For another example, patent CN110170895B discloses a process for manufacturing neodymium iron boron convenient for polishing, which comprises the following steps: a. profiling: pressing the stirred and ground powder into a long cylindrical shape in a grinding tool; b. and (3) feeding: fixing a cylindrical magnet on a workbench; c. cutting: cutting the long cylindrical magnet into segments with specified lengths; d. deburring: and removing burrs at the edges of the segmented magnets by a magnet edging device.

However, the prior art disclosed above has problems in that: the prior polishing equipment does not disclose a related technology for synchronously polishing the upper, lower, left and right surfaces of the batched cuboid sheet-shaped magnetic materials by using the same polishing equipment when polishing the magnetic materials.

Disclosure of Invention

Accordingly, the invention aims to provide a polishing processing assembly and an automatic magnet swinging device, which solve the problem that the conventional polishing equipment cannot synchronously polish the upper, lower, left and right surfaces of a batch of cuboid flaky magnet.

The invention discloses a polishing processing assembly, which comprises a polishing platform, wherein the bottom side of the polishing platform is a supporting part, the top side of the polishing platform is an assembling part, a first polishing frame body and a second polishing frame body are arranged on the supporting part of the polishing platform at intervals, a section I limiting groove body of the assembling part is positioned at one side of the first polishing frame body far away from the second polishing frame body, and a section II limiting groove body of the assembling part is positioned between the first polishing frame body and the second polishing frame body; at least one transport unit is arranged below the I-section limit groove body and the II-section limit groove body of the assembly part respectively, the I-section limit groove body corresponds to the transport units below the II-section limit groove body one by one, and the transport units are connected to the support part; a first driving unit for driving the transportation unit to rotate is arranged on one side of the grinding platform, a bottom grinding unit for grinding the bottom surface of the cuboid sheet magnetic material is arranged on the single first grinding frame body, a top grinding unit for grinding the top surface of the cuboid sheet magnetic material is arranged above the single bottom grinding unit, the top grinding unit is connected to a lifting part of the supporting arm, and the supporting arm is connected to a supporting part of the grinding platform through an elastic component; an output shaft of the first driving unit is provided with an eccentric wheel, and the eccentric wheel is opposite to the pressing part of the supporting arm; when the large end of the eccentric wheel is opposite to the pressing part of the supporting arm, the large end of the eccentric wheel is in clearance fit with the pressing part of the supporting arm; when the small end of the eccentric wheel is opposite to the pressing part of the supporting arm, the small end of the eccentric wheel abuts against the pressing part of the supporting arm to move downwards.

As a limiting scheme for the I-section limiting groove body and the II-section limiting groove body: the I section limiting groove body and the II section limiting groove body are respectively provided with at least one channel, the channels of the I section limiting groove body and the channels of the II section limiting groove body are in one-to-one correspondence, and the channels are used for the passage of cuboid sheet magnetic materials.

As a limiting solution for the bottom grinding unit: the bottom grinding unit comprises a first grinding belt, the outer surface of the first grinding belt is provided with polishing sand paper, the first grinding belt is connected with a middle groove of the first grinding frame body, the first grinding belt is connected with a first grinding motor for driving the first grinding belt to rotate, and the first grinding motor is connected with the first grinding frame body; the rotation direction of the first grinding belt is consistent with the rotation direction of the conveying belt.

As a limiting solution for the top grinding unit: the top grinding unit comprises a second grinding belt, the second grinding belt is connected with the lifting part of the supporting arm, and the second grinding belt corresponds to the first grinding belt one by one; the lifting part of the supporting arm is connected with a second grinding motor for driving the second grinding belt to rotate, and the rotation directions of the first grinding belt and the second grinding belt are opposite; the outer surface of the second polishing belt is provided with polishing sand paper.

As an optimization scheme of the polishing processing assembly: the polishing processing assembly further comprises a transverse positioning unit, and the transverse positioning unit is arranged on one side of the bottom polishing unit and on the first grinding frame body; the transverse positioning unit comprises a first bidirectional screw, two ends of the first bidirectional screw are rotationally connected with the supporting part of the grinding platform, left side threads and right side threads which are opposite in rotation direction are respectively formed at two ends of the first bidirectional screw, and the left side threads and the right side threads of the first bidirectional screw are respectively in threaded connection with a left clamping plate and a right clamping plate; the left clamping plate and the right clamping plate are respectively connected with the grooves on two sides of the first grinding frame body in a sliding manner, and are arranged on two sides of the bottom grinding unit; the first bidirectional screw rod is connected with the supporting arm through the linkage unit.

As a limiting scheme for the linkage unit: the linkage unit comprises a transmission gear, the transmission gear is concentrically connected with the first bidirectional screw, one side of the transmission gear is provided with a toothed plate, the toothed plate and the transmission gear form meshed linkage, and the toothed plate is connected on the arm body of the support arm; when the second polishing belt is contacted with the top surface of the cuboid sheet magnetic material on the first polishing belt, the left clamping plate and the right clamping plate are contacted with the left surface and the right surface of the cuboid sheet magnetic material.

As an optimization scheme for the polishing processing assembly: the polishing processing assembly further comprises a side end face grinding unit, the side end face grinding unit is arranged on the second grinding frame body, and the single side end face grinding unit is opposite to the upper channel of the II-section limiting groove body on the adjacent side; the side end face grinding unit is used for grinding the left and right surfaces of the cuboid sheet magnetic material.

As an optimization scheme for the polishing processing assembly: and a vertical positioning unit is further arranged above the single side end face grinding unit and used for positioning the cuboid sheet-shaped magnetic materials with the left and right surfaces polished.

The invention discloses an automatic magnetic material arranging device, which comprises a polishing and processing assembly, wherein one side of the polishing and processing assembly is provided with a mechanical arm vision robot and a feeding frame, and the mechanical arm vision robot is used for arranging a cuboid sheet-shaped magnetic material polished on the polishing and processing assembly into the feeding frame; the placing component is arranged on one side of the II-section limiting groove body of the polishing processing component; a belt conveyor is arranged below the placement assembly, and a diffusion disc body is placed on the belt conveyor.

As an optimization scheme for the automatic magnetic material arranging device: the placing component comprises a bearing frame, one side of the bearing frame is provided with a longitudinal driving unit, a movable sliding block of the longitudinal driving unit is connected with a joist, and the other end of the joist is in sliding connection with the other side of the bearing frame; the joist is provided with a transverse driving unit, a movable sliding block of the transverse driving unit is connected with a vertical driving unit, a movable sliding block of the vertical driving unit is connected with a sponge sucker, and the sponge sucker is connected with a miniature vacuum pump.

The invention has the beneficial effects that:

according to the invention, by combining the polishing processing assembly, the top grinding unit and the conveying unit can be synchronously linked by utilizing the same driving source (the first driving unit), so that the energy consumption is saved to a certain extent; on the other hand, compared with the prior art in the background art, the movable rectangular sheet-shaped magnetic material polishing device can polish the upper surface and the lower surface of the movable rectangular sheet-shaped magnetic material, and solves the problem that the conventional polishing device cannot polish the upper surface, the lower surface, the left surface and the right surface of the batch of rectangular sheet-shaped magnetic materials synchronously.

Drawings

Fig. 1 is a schematic view of the appearance structure of a rectangular sheet-like magnetic material.

Fig. 2 is a flow chart of processing a rectangular parallelepiped sheet-shaped magnetic material.

Fig. 3 is a schematic perspective view of a sanding assembly.

Fig. 4 is a schematic view of the external appearance structure of the grinding platform.

Fig. 5 is a schematic view of a transport unit installation structure.

Fig. 6 is a schematic view of an assembled structure of the bottom grinding unit.

Fig. 7 is a schematic perspective view of the top grinding unit.

Fig. 8 is a state diagram of the first polishing belt and the second polishing belt after being contacted with the cuboid sheet magnetic material.

Fig. 9 is a view of a sanding processing assembly in use.

Fig. 10 is a schematic view of the mounting structure of the lateral positioning unit.

Fig. 11 is a schematic perspective view of two lateral positioning units.

Fig. 12 is a schematic view of the mounting structure of the side face grinding unit and the vertical positioning unit.

Fig. 13 is a schematic diagram showing an assembly structure of the side face grinding unit and the second grinding frame body.

Fig. 14 is a use state diagram of the side end face grinding unit, the vertical positioning unit, the top grinding unit, the bottom grinding unit, the transverse positioning unit and the two linkage units together acting to form a batch of cuboid sheet magnetic materials.

Fig. 15 is a schematic diagram of the overall structure of the magnetic material automatic swing device.

Fig. 16 is a schematic perspective view of a placement module.

In the figure, the section I and section 1 limit groove bodies; 2. II-stage limit groove body; 3. a channel; 4. a first grinding frame; 5. a second grinding frame body; 6. a conveyor belt; 7. a servo motor; 8. a drive belt; 9. a first drive roller shaft; 10. a second drive roller shaft; 11. a first abrasive belt; 12. polishing sand paper; 13. a first grinding motor; 14. a second polishing belt; 15. a support arm; 16. a second grinding motor; 17. positioning columns; 18. a spring; 19. an eccentric wheel; 20. a first bi-directional screw; 21. a first bump; 22. a left clamping plate; 23. a right clamping plate; 24. a transmission gear; 25. a toothed plate; 26. a second bidirectional screw; 27. a second bump; 28. a third polishing belt; 29. a moving plate; 30. a third grinding motor; 31. a pressing plate; 32. a mechanical arm vision robot; 33. a feeding frame; 34. a carrier; 35. MY1H type rodless cylinder; 36. joist; 37. DGCK type rodless cylinder; 38. CY3R15 rodless cylinder; 39. a sponge sucker; 40. a belt conveyor; 41. rectangular sheet magnetic material; 42. rectangular block-shaped magnetic material; 43. diffusion disc.

Detailed Description

In order to clearly understand the technical scheme of the application, a polishing processing assembly and a magnetic material automatic swing device provided by the application are described in detail below with reference to specific embodiments and drawings.

The terminology used in the following embodiments is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification and claims of this application, the singular forms "a," "an," "the," and "the" are intended to include, for example, "one or more" such forms of expression, unless the context clearly indicates to the contrary. It should also be understood that in the various embodiments herein below, "at least one", "one or more" means one, two or more than two.

Reference in the specification to "one embodiment" or "some embodiments" or the like means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the application. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," and the like in various places throughout this specification are not necessarily all referring to the same embodiment, but mean "one or more, but not all, embodiments" unless expressly specified otherwise. The terms "comprising," "including," "having," and variations thereof mean "including but not limited to," unless expressly specified otherwise.

Embodiment 1, this embodiment provides a polishing process assembly, referring to fig. 3-4, wherein fig. 3 shows a schematic perspective view of the polishing process assembly, fig. 4 shows a schematic view of an appearance structure of a grinding platform, and as shown in the above two figures, the polishing process assembly includes the grinding platform, a supporting portion is formed on a bottom side of the grinding platform, and an assembling portion is formed on a top side of the grinding platform; the assembly part of the grinding platform consists of two parts, namely a I-section limiting groove body 1 and a II-section limiting groove body 2, wherein the I-section limiting groove body 1 and the II-section limiting groove body 2 are respectively arranged at the left side and the right side of the supporting part of the grinding platform; two channels 3 extending along the length direction are formed on the I-section limiting groove body 1 and the II-section limiting groove body 2, and the two channels 3 on the I-section limiting groove body 1 and the two channels 3 on the II-section limiting groove body 2 respectively form a mutual corresponding relation; a first grinding frame body 4 is arranged between the upper channel 3 of the I-section limiting groove body 1 and the upper channel 3 of the II-section limiting groove body 2 on the adjacent side, and the grinding platform supporting part is connected with the first grinding frame body 4; and one end of the II-section limiting groove body 2, which is far away from the first grinding frame body 4, is provided with a second grinding frame body 5, and the second grinding frame body 5 is connected with a grinding platform supporting part.

Referring to fig. 3 and further in combination with the schematic view of the installation structure of the transport unit shown in fig. 5, the polishing assembly further includes a transport unit, where the transport unit includes four small-sized conveyor belts 6 of PKD1112 type, and the four conveyor belts 6 are installed in the two channels 3 of the i-stage limiting groove 1 and the two channels 3 of the ii-stage limiting groove 2, respectively; the left end and the right end of the single conveying belt 6 are respectively connected with a first transmission roll shaft 9 and a second transmission roll shaft 10, and the first transmission roll shaft 9 and the second transmission roll shaft 10 are in rotary connection with the supporting part; the two conveyor belts 6 on the left side of the supporting part are connected with the second transmission roll shaft 10, and the two conveyor belts 6 on the right side of the supporting part are connected with the first transmission roll shaft 9. The first driving unit is installed on one side of the grinding platform, in this embodiment, the first driving unit can directly select the existing product servo motor 7, the power output shaft of the servo motor 7 is connected with two driving belts 8, and the free ends of the two driving belts 8 are respectively connected with a second driving roll shaft 10 on the left conveying belt 6 of the supporting part and a first driving roll shaft 9 on the right conveying belt 6. And a bottom grinding unit for grinding the bottom surface of the rectangular sheet-like magnetic material 41 is mounted on the single first grinding frame 4, and the specific structure of the bottom grinding unit is as follows.

Referring to fig. 6, there is shown a schematic diagram of an assembly structure of a bottom grinding unit, which is seen to include a first grinding belt 11, on an outer surface of which a YS2779 type 60-mesh polishing sandpaper 12 is bonded, the first grinding belt 11 being interposed between first grinding frames 4; the two ends of the first grinding belt 11 are respectively and rotatably connected with the middle groove of the first grinding frame body 4 through a rotating shaft body, the rotating shaft body is connected with the output shaft of the first grinding motor 13 through a transmission belt, and the first grinding motor 13 is fixedly connected to the first grinding frame body 4; the direction of rotation of the first grinding belt 11 coincides with the direction of rotation of the conveyor belt 6. Referring to fig. 3, a top grinding unit for grinding the top surface of the rectangular parallelepiped sheet-shaped magnetic material 41 is provided above the single bottom grinding unit, and the specific structure of the top grinding unit is as follows.

Referring to fig. 7 and further referring to fig. 3, in which fig. 7 is a schematic perspective view of a top grinding unit, it can be seen from the above two views that the top grinding unit includes two second grinding belts 14, and the two second grinding belts 14 are respectively rotatably connected to two side edges of the lifting portion of the supporting arm 15, and the two second grinding belts 14 are respectively opposite to the two first grinding belts 11; the lifting part of the supporting arm 15 is connected with a second grinding motor 16 for driving the second grinding belt 14 to rotate, and the rotation directions of the first grinding belt 11 and the second grinding belt 14 are consistent; similarly, the outer surface of the second sanding belt 14 is also bonded with YS2779 type 60 mesh polishing sand paper 12; the two positioning columns 17 movably penetrate through the left end and the right end of the lifting part and are fixedly connected with the supporting part of the grinding platform; an elastic component (such as a spring 18) is sleeved on each positioning column 17, and two ends of the elastic component are respectively abutted against the lifting part of the supporting arm 15 and the supporting part of the grinding platform; an eccentric wheel 19 is arranged above the pressing part of the supporting arm 15, and the wheel center of the eccentric wheel 19 is connected with a power output shaft of the first driving unit; whenever the large end of the eccentric wheel 19 is opposite to the pressing part of the supporting arm 15, the large end of the eccentric wheel 19 is in clearance fit with the pressing part of the supporting arm 15, and the elastic component is in a natural state; when the small end of the eccentric wheel 19 is opposite to the pressing portion of the supporting arm 15, the small end of the eccentric wheel 19 abuts against the pressing portion of the supporting arm 15 to move downwards, and the elastic component is in a compressed state.

The present embodiment defines at the same time: when the pressing part of the small end pressing support arm 15 of the eccentric wheel 19 reaches the lowest point, referring to fig. 8, a state diagram of the first grinding belt 11 and the second grinding belt 14 after contacting with the cuboid sheet magnetic material 41 is shown, it can be seen from the diagram that the cuboid sheet magnetic material 41 completely moves onto the first grinding belt 11, and the second grinding belt 14 contacts with the top surface of the cuboid sheet magnetic material 41 on the first grinding belt 11.

The overall working mode of the polishing processing assembly is as follows: first, referring to the state diagram of the polishing process assembly shown in fig. 9, it can be seen from the figure that after the batch of cuboid sheet magnetic materials 41 completes the process of the previous process, two rows of cuboid sheet magnetic materials 41 are moved onto the two left conveyor belts 6 and into the two channels 3 of the i-stage limiting groove body 1, the conveyor belts 6 on the left and right sides synchronously rotate along the a1 direction by the power of the first driving unit, and simultaneously, the first grinding motor 13 and the second grinding motor 16 are synchronously started to enable the first polishing belt 11 and the second polishing belt 14 to respectively move along the a1 and the a2 directions. Then, when the cuboid sheet magnetic material 41 completely moves to the upper surface of the first grinding belt 11, the small end of the eccentric wheel 19 is pressed against the supporting arm 15 along the direction b1 to move downwards, and the downwards moving supporting arm 15 enables the second grinding belt 14 to contact with the top surface of the cuboid sheet magnetic material 41 on the first grinding belt 11; at this time, since the first and second grinding belts 11, 14 move in the a1, a2 directions, respectively, the coated abrasive 12 of the first and second grinding belts 11, 14 can thoroughly grind the upper and lower surfaces of the rectangular parallelepiped sheet-shaped magnetic material 41. Finally, referring to fig. 3, when the small end of the eccentric wheel 19 is separated from the supporting arm 15, the supporting arm 15 returns to the original position along the direction b2 under the action of the elastic component, the second polishing belt 14 is separated from contact with the cuboid sheet magnetic material 41, and the cuboid sheet magnetic material 41 continues to move along the direction a1 under the drive of the first polishing belt 11.

According to the invention, by combining the polishing processing assembly, the top grinding unit and the conveying unit can be synchronously linked by utilizing the same driving source (the first driving unit), so that the energy consumption is saved to a certain extent; on the other hand, compared with the prior art in the background art, the movable rectangular sheet-shaped magnetic material 41 can be polished on the upper surface and the lower surface, and the problem that the conventional polishing equipment cannot synchronously polish the upper surface, the lower surface, the left surface and the right surface of the batch of rectangular sheet-shaped magnetic materials 41 is solved.

As a first set of optimization schemes for the sanding assembly: when the cuboid sheet magnetic material 41 is polished by the polishing sand paper 12 on the first polishing belt 11 and the second polishing belt 14, if the position of the cuboid sheet magnetic material 41 is not positioned in time, the cuboid sheet magnetic material 41 is likely to shift; for this reason, in view of the fact that the upper and lower surfaces of the rectangular parallelepiped sheet-like magnetic material 41 are easily displaced during grinding, the present invention further designs a lateral positioning unit, which is mounted on the side of the bottom grinding unit on the first grinding frame 4 as seen from the installation structure diagram of the lateral positioning unit shown in fig. 10, with the following specific structure.

Referring to fig. 11 in combination with fig. 10, in which fig. 11 shows a schematic perspective view of two lateral positioning units, it can be seen from the above two views that a single lateral positioning unit includes a first bidirectional screw rod 20, two ends of the first bidirectional screw rod 20 are respectively in rotational connection with the proximal end of the supporting part of the grinding platform through a first bump 21, two ends of the first bidirectional screw rod 20 are respectively formed with a left side thread and a right side thread, and the directions of the threads of the left side thread and the right side thread are opposite; the left side thread and the right side thread of the first bidirectional screw rod 20 are respectively provided with a left clamping plate 22 and a right clamping plate 23, and the left clamping plate 22 and the right clamping plate 23 are respectively provided with threaded holes which are used for being matched with the left side thread and the right side thread; the left clamping plate 22 and the right clamping plate 23 are respectively and slidably connected in the grooves on two sides of the first grinding frame body 4 and are arranged on two sides of the bottom grinding unit; adjacent ends of the first two-way screws 20 of adjacent two lateral positioning units are connected. One side of the first bidirectional screw 20 is provided with a linkage unit, wherein the linkage unit comprises a transmission gear 24, the transmission gear 24 is concentrically connected to the first bidirectional screw 20, one side of the transmission gear 24 is provided with a toothed plate 25, the toothed plate 25 is meshed with the transmission gear 24 and is in linkage, and the other end of the toothed plate 25 is connected with one end of the arm body of the support arm 15.

The present embodiment defines at the same time: referring to fig. 10, when the second polishing belt 14 contacts with the top surface of the rectangular sheet magnetic material 41 on the first polishing belt 11, the supporting arm 15 drives the toothed plate 25 to move downward along the b1 direction, and the toothed plate 25 rotates along the c1 direction in linkage with the transmission gear 24 and the first bidirectional screw 20; the first grinding frame 4 and the first bidirectional screw 20 together define a left clamping plate 22 and a right clamping plate 23 which move to contact with the left and right surfaces of the rectangular sheet-shaped magnetic material 41.

A second set of optimization schemes for the sanding assembly: in the process of polishing the rectangular sheet-shaped magnetic material 41, the upper and lower surfaces of the rectangular sheet-shaped magnetic material 41 are required to be polished, and the left and right surfaces of the rectangular sheet-shaped magnetic material 41 are required to be polished; for this reason, this embodiment further designs a side end face grinding unit, as shown in fig. 12, which is a schematic diagram of the installation structure of the side end face grinding unit and the vertical positioning unit, where two side end face grinding units are respectively installed on two sides of the second grinding frame 5, and a single side end face grinding unit is opposite to the channel 3 on the ii-segment limiting groove 2 on the adjacent side; the specific structure of the side face grinding unit is as follows.

Referring to fig. 13 in combination with fig. 12, in which fig. 13 shows a schematic diagram of an assembly structure of a side end face grinding unit and a second grinding frame 5, it can be seen from the above two drawings that a single side end face grinding unit includes a second bidirectional screw 26, the second bidirectional screw 26 is in a rotational connection with a proximal end of a supporting portion of a grinding platform through a second bump 27, and the second bidirectional screw 26 has the same structure as the first bidirectional screw 20, and is not repeated herein; the left side threads and the right side threads of the first bidirectional screw rod 20 are respectively in threaded connection with a left polishing piece and a right polishing piece, two sides of the second grinding frame body 5 are respectively provided with side grooves, and the left polishing piece and the right polishing piece are in sliding connection with the two side grooves on the second grinding frame body 5; the left grinding piece or the right grinding piece specifically comprises a third grinding belt 28, the third grinding belt 28 is rotationally connected to a moving plate 29, a power output shaft of a third grinding motor 30 is in transmission connection with the third grinding belt 28, and the third grinding motor 30 is fixedly connected with the moving plate 29; screw holes for matching with left and right side threads of the first bidirectional screw 20 are respectively formed in the two moving plates 29.

With further reference to fig. 12, a vertical positioning unit is arranged above the single side end face grinding unit, the vertical positioning unit is a pressing plate 31, and the pressing plate 31 is connected to the lifting part of the supporting arm 15; the lower surface of the pressing plate 31 forms a bulge, and the bulge of the pressing plate 31 is arranged above the left polishing piece and the right polishing piece. One side of the side face grinding unit is provided with another linkage unit, wherein the linkage unit has the same structure as the linkage unit, a transmission gear 24 of the linkage unit is concentrically connected with one end of a second bidirectional screw 26, and a toothed plate 25 of the linkage unit is connected with the other end of the arm body of the supporting arm 15.

The present embodiment defines at the same time: when one of the rectangular sheet-like magnetic materials 41 is completely moved onto the first grinding belt 11 of the bottom grinding unit, the other rectangular sheet-like magnetic material 41 falls onto the second grinding frame 5 corresponding to the first grinding belt 11 and between the left grinding member and the right grinding member, and the protrusions of the left grinding member, the right grinding member and the pressing plate 31 are respectively contacted with the left, right and top surfaces of the rectangular sheet-like magnetic material 41.

The working principle of the side end face grinding unit, the vertical positioning unit and the linkage unit at the side end face grinding unit is as follows: referring to fig. 12, when the support arm 15 moves downward along the b1 direction, the support arm 15 further drives the toothed plate 25 of the linkage unit to move downward synchronously, and the toothed plate 25 of the linkage unit rotates in linkage with the corresponding transmission gear 24 and the second bidirectional screw 26; the left grinding member and the right grinding member approach each other along d1 and d2, respectively, under the joint definition of the rotating second bidirectional screw 26 and the side groove of the second grinding frame 5. Then, referring to fig. 14, a usage state diagram of the batch of cuboid sheet magnetic materials 41 is shown by the combined action of the side end face grinding unit, the vertical positioning unit, the top grinding unit, the bottom grinding unit, the horizontal positioning unit and the two linkage units, until the cuboid sheet magnetic materials 41 fall onto the second grinding frame 5 between the left grinding piece and the right grinding piece, the third grinding belts 28 of the left grinding piece and the right grinding piece are respectively contacted with the left surface and the right surface of the cuboid sheet magnetic materials 41, and the pressing plate 31 is raised to limit the top surface of the cuboid sheet magnetic materials 41; meanwhile, the second polishing belt 14 contacts with the other cuboid sheet magnetic material 41 on the first polishing belt 11, and the lateral positioning unit limits the other cuboid sheet magnetic material 41 on the polishing belt.

Embodiment 2, this embodiment provides an automatic magnet arranging device, refer to fig. 15, which shows an overall structure schematic diagram of the automatic magnet arranging device, as shown in the drawing, the automatic magnet arranging device includes a polishing component, one side of the polishing component is provided with a mechanical arm vision robot 32 and a feeding frame 33, the mechanical arm vision robot 32 uses the existing product on the market, the model is DOFBOT, and the mechanical arm vision robot 32 is mainly used for arranging the polished cuboid sheet-shaped magnet 41 on the polishing component into the feeding frame 33. In addition, the automatic magnetic material arranging device also comprises a placing component which is arranged on one side of the II-section limiting groove body 2 of the polishing processing component; the specific structure of the placement component is as follows.

Referring to fig. 16, a schematic perspective view of a placement component is shown, where the placement component includes a carrier 34, a longitudinal driving unit is disposed on a right side bearing arm of the carrier 34, where the longitudinal driving unit may be a rodless cylinder with a model of MY1H, a joist 36 is connected to a moving slide block of the MY1H rodless cylinder 35, and another end of the joist 36 forms a sliding connection with a left side bearing arm of the carrier 34; the joist 36 is provided with a transverse driving unit which can be a DGCK type rodless cylinder 37; the movable slide block of the DGCK type rodless cylinder 37 is connected with a vertical driving unit, and the CY3R15 type rodless cylinder 38 can be used as the vertical driving unit; the movable slide block of the CY3R15 rodless cylinder 38 is connected with a sponge sucker 39 (model GJ2R 316U), and the sponge sucker 39 is connected with a micro vacuum pump (model SCL series, not shown in the figure).

With continued reference to fig. 15, a belt conveyor 40 is mounted below the placement module, where the belt conveyor 40 is of the HST-03 type and a diffusion disc 43 is placed on the HST-03 type belt conveyor 40.

The whole working mode of the automatic magnetic material arranging device is as follows: firstly, polishing the cuboid sheet magnetic material 41 through a polishing assembly, and placing the cuboid sheet magnetic material 41 into a feeding frame 33 by using a mechanical arm vision robot 32; then, the position of the sponge sucker 39 is adjusted by utilizing a longitudinal driving unit, a transverse driving unit and a vertical driving unit of the placement assembly, so that the cuboid sheet magnetic material 41 is adsorbed, the cuboid sheet magnetic material 41 is transferred and the cuboid sheet magnetic material 41 is placed in the diffusion disc body 43 in sequence; finally, the diffusion disc 43 with the bulk rectangular parallelepiped sheet-like magnetic material 41 placed thereon is transported to the next processing station (e.g., diffusion apparatus) by the belt conveyor 40.

Claims (10)

1. A grinding machining assembly, characterized in that: the grinding machine comprises a grinding platform, wherein the bottom side of the grinding platform is a supporting part, the top side of the grinding platform is an assembling part, a first grinding frame body (4) and a second grinding frame body (5) are arranged on the supporting part of the grinding platform at intervals, a section I limiting groove body (1) of the assembling part is positioned on one side, far away from the second grinding frame body (5), of the first grinding frame body (4), and a section II limiting groove body (2) of the assembling part is positioned between the first grinding frame body (4) and the second grinding frame body (5); at least one transport unit is arranged below the I-section limit groove body (1) and the II-section limit groove body (2) of the assembly part respectively, the I-section limit groove body (1) corresponds to the transport units below the II-section limit groove body (2) one by one, and the transport units are connected to the support part; a first driving unit for driving the transportation unit to rotate is arranged on one side of the grinding platform, a bottom grinding unit for grinding the bottom surface of the cuboid sheet magnetic material is arranged on the single first grinding frame body (4), a top grinding unit for grinding the top surface of the cuboid sheet magnetic material is arranged above the single bottom grinding unit, the top grinding unit is connected to a lifting part of the supporting arm (15), and the supporting arm (15) is connected to a supporting part of the grinding platform through an elastic component; an output shaft of the first driving unit is provided with an eccentric wheel (19), and the eccentric wheel (19) is opposite to the pressing part of the supporting arm (15); when the large end of the eccentric wheel (19) is opposite to the pressing part of the supporting arm (15), the large end of the eccentric wheel (19) is in clearance fit with the pressing part of the supporting arm (15); when the small end of the eccentric wheel (19) is opposite to the pressing part of the supporting arm (15), the small end of the eccentric wheel (19) abuts against the pressing part of the supporting arm (15) to move downwards.

2. The sanding processing assembly of claim 1, wherein: at least one channel (3) is arranged on the I-section limiting groove body (1) and the II-section limiting groove body (2) respectively, the channel (3) of the I-section limiting groove body (1) corresponds to the channel (3) of the II-section limiting groove body (2) one by one, and the channel (3) is used for the passage of cuboid flaky magnetic materials.

3. The abrasive machining assembly of claim 2, wherein: the bottom grinding unit comprises a first grinding belt (11), the outer surface of the first grinding belt (11) is provided with polishing sand paper (12), the first grinding belt (11) is connected with a middle groove of the first grinding frame body (4), the first grinding belt (11) is connected with a first grinding motor (13) for driving the first grinding belt (11) to rotate, and the first grinding motor (13) is connected with the first grinding frame body (4); the rotation direction of the first grinding belt (11) is consistent with the rotation direction of the conveying belt (6).

4. A sanding processing assembly as defined in claim 3, wherein: the top grinding unit comprises a second grinding belt (14), the second grinding belt (14) is connected with the lifting part of the supporting arm (15), and the second grinding belt (14) corresponds to the first grinding belt (11) one by one; the lifting part of the supporting arm (15) is connected with a second grinding motor (16) for driving the second grinding belt (14) to rotate, and the rotation directions of the first grinding belt (11) and the second grinding belt (14) are opposite; the outer surface of the second polishing belt (14) is provided with polishing sand paper (12).

5. The abrasive machining assembly of claim 4, wherein: the grinding machine also comprises a transverse positioning unit, wherein the transverse positioning unit is arranged on one side of the bottom surface grinding unit and on the first grinding frame body (4); the transverse positioning unit comprises a first bidirectional screw (20), two ends of the first bidirectional screw (20) are rotationally connected with a supporting part of the grinding platform, left side threads and right side threads which are opposite in rotation are respectively formed at two ends of the first bidirectional screw (20), and the left side threads and the right side threads of the first bidirectional screw (20) are respectively in threaded connection with a left clamping plate (22) and a right clamping plate (23); the left clamping plate (22) and the right clamping plate (23) are respectively connected with the grooves on the two sides of the first grinding frame body (4) in a sliding manner, and the left clamping plate (22) and the right clamping plate (23) are arranged on the two sides of the bottom grinding unit; the first bidirectional screw rod (20) is connected with the supporting arm (15) through a linkage unit.

6. The abrasive machining assembly of claim 5, wherein: the linkage unit comprises a transmission gear (24), the transmission gear (24) is concentrically connected with the first bidirectional screw (20), one side of the transmission gear (24) is provided with a toothed plate (25), the toothed plate (25) and the transmission gear (24) form meshing linkage, and the toothed plate (25) is connected to the arm body of the support arm (15); when the second grinding belt (14) is contacted with the top surface of the cuboid sheet magnetic material on the first grinding belt (11), the left clamping plate (22) and the right clamping plate (23) are contacted with the left surface and the right surface of the cuboid sheet magnetic material.

7. The abrasive machining assembly of claim 6, wherein: the grinding device also comprises a side end face grinding unit, wherein the side end face grinding unit is arranged on the second grinding frame body (5), and a single side end face grinding unit is opposite to the upper channel (3) of the II-section limiting groove body (2) on the adjacent side; the side end face grinding unit is used for grinding the left and right surfaces of the cuboid sheet magnetic material; the side end face grinding unit comprises a second bidirectional screw rod 26, and the second bidirectional screw rod 26 is in rotary connection with the near end of the supporting part of the grinding platform; the left side threads and the right side threads of the first bidirectional screw rod 20 are respectively in threaded connection with a left polishing piece and a right polishing piece, two sides of the second grinding frame body 5 are respectively provided with side grooves, and the left polishing piece and the right polishing piece are in sliding connection with the two side grooves on the second grinding frame body 5; the left grinding piece or the right grinding piece specifically comprises a third grinding belt 28, the third grinding belt 28 is rotationally connected to a moving plate 29, a power output shaft of a third grinding motor 30 is in transmission connection with the third grinding belt 28, and the third grinding motor 30 is fixedly connected with the moving plate 29; screw holes for matching with left and right side threads of the first bidirectional screw 20 are respectively formed in the two moving plates 29.

8. The abrasive machining assembly of claim 7, wherein: a vertical positioning unit is further arranged above the single side end face grinding unit and used for positioning the cuboid sheet-shaped magnetic materials polished on the left and right surfaces; the vertical positioning unit is a pressing plate 31, and the pressing plate 31 is connected to the lifting part of the supporting arm 15; the lower surface of the pressing plate 31 forms a bulge, and the bulge of the pressing plate 31 is arranged above the left polishing piece and the right polishing piece.

9. An automatic magnet material arranging device is characterized in that: the polishing assembly comprises the polishing assembly as claimed in claim 8, wherein a mechanical arm vision robot (32) and a feeding frame (33) are arranged on one side of the polishing assembly, and the mechanical arm vision robot (32) is used for swinging the cuboid sheet-shaped magnetic material polished on the polishing assembly into the feeding frame (33); the placing component is arranged at one side of the II-section limiting groove body (2) of the polishing processing component; a belt conveyor (40) is arranged below the placement assembly, and a diffusion disc body (43) is placed on the belt conveyor (40).

10. The automatic magnet material arranging device according to claim 9, wherein: the placing assembly comprises a bearing frame (34), one side of the bearing frame (34) is provided with a longitudinal driving unit, a movable sliding block of the longitudinal driving unit is connected with a joist (36), and the other end of the joist (36) is in sliding connection with the other side of the bearing frame (34); the joist (36) is provided with a transverse driving unit, a movable sliding block of the transverse driving unit is connected with a vertical driving unit, a movable sliding block of the vertical driving unit is connected with a sponge sucker (39), and the sponge sucker (39) is connected with a miniature vacuum pump.