CN218548117U - Device for synchronously placing multiple fan-shaped magnets - Google Patents

Abstract

The application discloses a device for synchronously placing a plurality of fan-shaped magnets, which comprises a bearing seat, wherein a limiting body is arranged on the bearing seat, and a limiting channel is formed between the bearing seat and the limiting body; at least two fan-shaped through grooves are formed in the limiting body, the fan-shaped through grooves vertically extend in the limiting body, the fan-shaped through grooves are annularly arrayed, and a barrier is formed between every two adjacent fan-shaped through grooves; the magnetic pushing bottom plate is horizontally and slidably matched in the limiting channel, one end of the magnetic pushing bottom plate is a smooth surface, and the smooth surface is slidably attached to the limiting body; a pit is formed at the other end of the magnetism pushing bottom plate, and a jig is placed in the pit in a matched mode; the fixture is provided with more than two fan-shaped grooves in an annular array, a partition is formed between every two adjacent fan-shaped grooves, and the number of the fan-shaped grooves on the fixture is equal to that of the fan-shaped through grooves on the limiting body and the number of the fan-shaped through grooves on the limiting body are in one-to-one correspondence; the problem that single fan-shaped magnet combination wastes time and energy for annular magnet group in-process is solved to this application, and need artifical many times to carry out the combination to fan-shaped magnet in the solution conventional art problem.

Description

Device for synchronously placing multiple fan-shaped magnets

Technical Field

The utility model relates to a relevant technical field of magnet equipment, concretely relates to put device of a plurality of fan-shaped magnets in step.

Background

In the actual production process of the magnet, according to the design requirements of different products, magnets with different numbers and different shapes need to be combined into different types of magnet groups, and currently, a traditional magnet group (referring to fig. 1, a three-dimensional structure display diagram of a single sector magnet and a complete ring magnet group is shown) exists in the market; firstly, a single sector magnet (after being magnetized) is composed of an inner sector magnet and an outer sector magnet (the structures of the inner sector magnet and the outer sector magnet can be seen from a in figure 1), and the inner sector magnet and the outer sector magnet are adsorbed together through self magnetism; then, several individual sector magnets are combined into a ring magnet group (as can be seen from b in fig. 1); finally, a ring iron is bonded to the bottom of the ring magnet assembly (see c in fig. 1).

At present, in the process of combining a plurality of single sector magnets into a ring magnet group, the following problems exist: workers can only manually place the single fan-shaped magnets and combine the fan-shaped magnets into an annular magnet group; every time an annular magnet group is formed, a plurality of fan-shaped magnets need to be manually combined for many times, time and labor are wasted, and the working efficiency is low.

Disclosure of Invention

In view of this, the utility model aims at providing a device of a plurality of fan-shaped magnet is put in step solves single fan-shaped magnet combination and for the problem that the annular magnet group in-process wastes time and energy, and solves the problem that needs the manual work to make up fan-shaped magnet many times among the conventional art.

The utility model discloses a device for synchronously placing a plurality of fan-shaped magnets, which comprises a bearing seat, a limiting body is arranged on the bearing seat, and a limiting channel is formed between the bearing seat and the limiting body; at least two fan-shaped through grooves are formed in the limiting body, the fan-shaped through grooves vertically extend in the limiting body, the fan-shaped through grooves are annularly arrayed, and a barrier is formed between every two adjacent fan-shaped through grooves; the magnetic pushing bottom plate is horizontally and slidably matched in the limiting channel, one end of the magnetic pushing bottom plate is a smooth surface, and the smooth surface is slidably attached to the limiting body; a pit is formed at the other end of the magnetism pushing bottom plate, and a jig is placed in the pit in a matched mode; the annular array has more than two fan-shaped grooves on the tool, forms between the adjacent fan-shaped groove and separates the fender, and fan-shaped groove on the tool is the same with fan-shaped logical groove quantity on the spacing body and one-to-one. The jig is characterized in that a driving source is further connected to the jig, specifically, the driving source comprises an electric telescopic cylinder, the electric telescopic cylinder is fixed to the bearing seat, a lifting plate is connected to a power telescopic rod of the electric telescopic cylinder, and the lifting plate is connected with the magnetic pushing bottom plate.

As an optimization scheme for the driving source, the electric telescopic cylinder is provided with a first groove, the lifting plate is provided with a second groove, and the first groove and the second groove are matched in a sliding mode.

As the further optimization to this application, this application still includes adsorption component, and adsorption component assembles on the tool, and is concrete, and adsorption component includes the adsorption plate, is formed with the standing groove on the tool, is formed with the arch on the adsorption plate, and arch and standing groove mutual adaptation, the arch is connected with adsorbs ironware.

As an optimization scheme for the adsorption assembly, the fan-shaped grooves are communicated with the placing grooves through holes.

The beneficial effects of the utility model reside in that following several:

firstly, the bearing seat, the vertical plate, the limiting body, the magnetic pushing bottom plate and the jig are combined, manual arrangement of the fan-shaped magnets is replaced in a mechanical and automatic mode, the fan-shaped magnets can be synchronously arranged, and the working strength is reduced; on the other hand, this application can realize circulation, automatic putting with the annular magnet group of multiunit, need not the manual work and makes up a plurality of fan-shaped magnet many times, labour saving and time saving, and work efficiency is high.

Drawings

Fig. 1 is a perspective view of a single sector magnet and a complete ring magnet set.

Fig. 2 is a schematic overall structure diagram of the present application.

Fig. 3 is a schematic perspective view of the stopper.

Fig. 4 is a schematic view of an assembly structure of the vertical plate and the magnetic pushing bottom plate.

Fig. 5 is a flowchart of the work of the present application.

Fig. 6 is an assembly structure diagram of the driving source.

Fig. 7 is a schematic view of an assembly structure of the adsorption assembly.

In the figure, a bearing seat 1, a vertical plate 2, a limiting body 3, a fan-shaped through groove 4, a baffle 5, a magnetic pushing bottom plate 6, a pit groove 7, a jig 8, a fan-shaped groove 9, an electric telescopic cylinder 10, a lifting plate 11, a first groove 12, a second groove 13, an adsorption plate 14, a placing groove 15, a protrusion 16, an adsorption iron piece 17, a through hole 18 and a fan-shaped magnet 19.

Detailed Description

For clear understanding of the technical solution of the present application, a detailed description will be given below of an apparatus for synchronously positioning a plurality of sector magnets 19 provided in the present application with reference to specific embodiments and accompanying drawings.

The terminology used in the following examples is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification of the present application and the appended claims, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, such as "one or more", unless the context clearly indicates otherwise. It should also be understood that in the following embodiments of the present application, "at least one", "one or more" means one, two or more.

Reference throughout this 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 present application. Thus, appearances of the phrases "one embodiment," "in some embodiments," "in other embodiments," or the like, in various places throughout this specification are not necessarily all referring to the same embodiment, but rather "one or more but not all embodiments" unless specifically stated otherwise. The terms "comprising," "including," "having," and variations thereof mean "including, but not limited to," unless expressly specified otherwise.

Example 1

The embodiment provides a device for synchronously placing a plurality of fan-shaped magnets 19, referring to fig. 2, which shows an overall structural schematic diagram of the present application, as shown in the figure, the device includes a bearing seat 1, two vertical plates 2 are welded on the left side of the bearing seat 1, a gap is formed between adjacent surfaces of the two vertical plates 2, a limiting body 3 is fixed (bolted) at the top ends of the two vertical plates 2, and the limiting body 3 and the two vertical plates 2 jointly form a limiting channel; as shown in fig. 3, a schematic perspective view of the limiting body 3 is shown, ten fan-shaped through grooves 4 are formed in the center of the upper surface of the limiting body 3, the fan-shaped through grooves 4 vertically extend in the body of the limiting body 3, the ten fan-shaped through grooves 4 are in an annular array, and barriers 5 are formed between adjacent fan-shaped through grooves 4 (the barriers 5 are used for shielding repulsive force generated between adjacent fan-shaped magnets 19).

As can be seen by combining the structures in fig. 1 and 4 (fig. 4 shows an assembly structure schematic diagram of the vertical plate 2 and the magnetic pushing bottom plate 6), the magnetic pushing bottom plate 6 is adapted in the limiting channel in a horizontal sliding manner, the upper surface of the right end of the magnetic pushing bottom plate 6 is a smooth surface, and the smooth surface of the magnetic pushing bottom plate 6 is attached to the bottom surface of the limiting body 3 and can slide; a pit 7 is formed on the upper surface of the left end of the magnetism pushing bottom plate 6, and the pit 7 is used for providing a limiting space for placing a jig 8; the jig 8 is correspondingly placed in the pit 7, and the side wall of the pit 7 can limit the horizontal movement of the jig 8; in order to ensure that the fan-shaped magnets 19 in the fan-shaped through grooves 4 can be smoothly limited on the jig 8 and form an annular magnet group, ten fan-shaped grooves 9 are formed on the upper surface of the jig 8, ten annular arrays of the fan-shaped grooves 9 are formed, a separating block 5 is formed between every two adjacent fan-shaped grooves 9, and the ten fan-shaped grooves 9 on the jig 8 and the ten fan-shaped through grooves 4 on the limiting body 3 form a one-to-one correspondence relationship.

The working principle of the application is as follows: referring to fig. 5, which shows a working flow chart of the present application, first, as shown in detail in a in fig. 5, a jig 8 is placed in a pit slot 7, so as to ensure that a smooth surface at the right end of a magnetic pushing bottom plate 6 is located below a limiting body 3, and the smooth surface blocks the bottom of a fan-shaped through slot 4 (note that more than two groups of ring-shaped magnet groups are required to be stacked in the through slot in advance, wherein ten fan-shaped magnets 19 are one group of ring-shaped magnet groups, and ten fan-shaped magnets 19 are respectively placed in ten fan-shaped through slots 4 in a number-to-number manner). Then, as shown in detail in fig. 5B, the magnetic pushing bottom plate 6 is pushed to the right until the ten fan-shaped grooves 9 on the jig 8 and the ten fan-shaped through grooves 4 on the limiting body 3 completely correspond to each other, the fan-shaped magnets 19 in the fan-shaped through grooves 4 fall into the corresponding fan-shaped through grooves 4, and the ten fan-shaped magnets 19 falling into the fan-shaped through grooves 4 form a complete ring-shaped magnet set again. Finally, as shown in detail in fig. 5C, the magnetic pushing bottom plate 6 is pushed leftward until the jig 8 in the pit 7 is completely separated from the limiting channel, and at this time, the ring-shaped iron member 21 is bonded above the ring-shaped magnet set.

According to the magnetic pushing device, the bearing seat 1, the vertical plate 2, the limiting body 3, the magnetic pushing bottom plate 6 and the jig 8 are combined, manual arrangement of the fan-shaped magnets 19 is replaced by a mechanical and automatic mode, the fan-shaped magnets 19 can be arranged synchronously, and the working strength is reduced; on the other hand, this application can realize circulation, automatic putting with the annular magnet group of multiunit, need not the manual work and makes up a plurality of fan-shaped magnet 19 many times, labour saving and time saving, and work efficiency is high.

Furthermore, in order to ensure that the ten fan-shaped grooves 9 on the jig 8 can be accurately aligned with the ten fan-shaped through grooves 4 on the limiting body 3 and also provide driving force for the movement of the jig 8, a driving source is further designed; specifically, as shown in fig. 6, an assembly structure diagram of the driving source is shown, the driving source includes an electric telescopic cylinder 10 (the electric telescopic cylinder 10 is a common existing product in the market, and according to an actual application situation, the driving source may be replaced by an air telescopic cylinder, etc.), the electric telescopic cylinder 10 is fixed on the upper surface of the bearing seat 1 by a bolt, a lifting plate 11 is welded on a power telescopic rod of the electric telescopic cylinder 10, and the lifting plate 11 is fixed below the magnetic pushing bottom plate 6. When the magnetic pushing base plate is used, the alignment of the fan-shaped grooves 9 and the fan-shaped through grooves 4 can be accurately realized by controlling the stretching amount of the electric stretching cylinder 10, and the magnetic pushing base plate 6 is driven to move by controlling the stretching amount of the electric stretching cylinder 10; wherein, bear and install the controller on the seat 1, the controller is the common prior art in the market for control electric telescopic cylinder 10.

As a further optimization of the driving source, in order to further enhance the bearing capacity of the electric telescopic rod, as can be seen from fig. 6, a first groove 12 is formed on the upper surface of the electric telescopic cylinder 10, and a second groove 13 capable of being matched with the limit groove is formed below the lifting plate 11.

Further, in order to guarantee that fan-shaped magnet 19 in fan-shaped logical groove 4 can enter into fan-shaped groove 9 fast, for this reason, this application has designed an adsorption component, and adsorption component assembles in the below of tool 8, and concrete structure is as follows.

As shown in fig. 7, the assembly structure diagram of the adsorption assembly is shown, and includes an adsorption plate 14, a placement groove 15 is formed below the jig 8 by stamping, a protrusion 16 is formed above the adsorption plate 14 by pressing, the protrusion 16 on the adsorption plate 14 is matched with the placement groove 15 on the jig 8, and an adsorption iron member 17 is bonded to the top of the protrusion 16. During the use, at first, assemble the arch 16 of adsorption plate 14, adsorb ironware 17 in the standing groove 15 of tool 8, through the adsorption affinity of adsorbing ironware 17, adsorb fan-shaped magnet 19 in the fan-shaped logical groove 4 fast to fan-shaped groove 9, work efficiency very promotes.

As a further optimization of the adsorption component, a small through hole 18 is opened at the bottom of the fan-shaped groove 9, the small through hole 18 is communicated with the placing groove 15, and the small through hole 18 enhances the adsorption force of the iron piece on the fan-shaped magnet 19 and ensures that the fan-shaped magnet 19 cannot pass through the small through hole 18. On the other hand, the jig 8 is made of a non-magnetic material (e.g., plastic) in order to avoid the influence of other components on the attraction ability of the attraction iron 17 and the sector magnet 19.

Claims (5)

1. A device for synchronously placing a plurality of fan-shaped magnets (19), is characterized in that: comprises a bearing seat (1), a limiting body (3) is arranged on the bearing seat (1), and a limiting channel is formed between the bearing seat (1) and the limiting body (3); at least two fan-shaped through grooves (4) are formed in the limiting body (3), the fan-shaped through grooves (4) vertically extend in the limiting body (3), the fan-shaped through grooves (4) are annularly arrayed, and a baffle (5) is formed between every two adjacent fan-shaped through grooves (4); the magnetic pushing bottom plate (6) is horizontally and slidably matched in the limiting channel, one end of the magnetic pushing bottom plate (6) is a smooth surface, and the smooth surface is slidably attached to the limiting body (3); a pit groove (7) is formed at the other end of the magnetism pushing bottom plate (6), and a jig (8) is placed in the pit groove (7) in a matched mode; the annular array has more than two fan-shaped grooves (9) on tool (8), forms between adjacent fan-shaped groove (9) and separates fender (5), fan-shaped groove (9) on tool (8) and fan-shaped logical groove (4) on spacing body (3) quantity equivalence and one-to-one.

2. Device for the simultaneous positioning of a plurality of sector magnets (19) according to claim 1, characterized in that: the output end of the driving source is connected with the jig (8); the driving source comprises an electric telescopic cylinder (10), the electric telescopic cylinder (10) is fixed with the bearing seat (1), a power telescopic rod of the electric telescopic cylinder (10) is connected with a lifting plate (11), and the lifting plate (11) is connected with the magnetic pushing bottom plate (6).

3. Device for the simultaneous positioning of a plurality of sector magnets (19) according to claim 2, characterized in that: a first groove (12) is formed in the electric telescopic cylinder (10), a second groove (13) is formed in the lifting plate (11), and the first groove (12) and the second groove (13) are matched in a sliding mode.

4. Device for the simultaneous positioning of a plurality of sector magnets (19) according to claim 1, characterized in that: the fixture is characterized by further comprising an adsorption component which is assembled below the fixture (8); wherein, adsorb the subassembly and include adsorption plate (14), be formed with standing groove (15) on tool (8), be formed with arch (16) on adsorption plate (14), arch (16) and standing groove (15) mutual adaptation, arch (16) are connected with and adsorb ironware (17).

5. Device for the simultaneous positioning of a plurality of sector magnets (19) according to claim 4, characterized in that: the fan-shaped groove (9) is communicated with the placing groove (15) through a through hole (18).

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