CN211920080U - Automatic feeding device for cylindrical neodymium iron boron magnet - Google Patents

Abstract

The utility model discloses an automatic feeding device for cylindrical neodymium iron boron magnet, aiming at providing an automatic feeding device for cylindrical neodymium iron boron magnet with high production efficiency, safety and reliability, which has the key points of the technical proposal that the automatic feeding device comprises a tool frame, and a first material storage plate, a second material storage plate, a first material transferring mechanism and a second material transferring mechanism which are arranged on the tool frame; a plurality of first accommodating spaces for accommodating materials are transversely arranged on the first storage plate, a second accommodating space opposite to one end of the first accommodating spaces is transversely arranged on the second storage plate, and a material guide part for guiding materials is arranged at the front end of the second storage plate; the first material transferring mechanism comprises a material pushing plate arranged at the other end of the first accommodating space and a first telescopic rod driving the material pushing plate to transversely move, and the first telescopic rod extends to drive the material pushing plate to move towards the second accommodating space, so that materials in the first accommodating space enter the second accommodating space; the utility model discloses be suitable for material feeding unit technical field.

Description

Automatic feeding device for cylindrical neodymium iron boron magnet

Technical Field

The utility model relates to a material feeding unit technical field, more precisely relate to an automatic feeding of cylindrical neodymium iron boron magnetism iron.

Background

Neodymium-iron-boron magnet (NdFeB magnet) is a tetragonal crystal formed of neodymium, iron, and boron (Nd2Fe 14B). The magnetic energy product (BHmax) of this magnet was greater than that of a samarium cobalt magnet, and was the largest in magnetic energy product worldwide at that time. This magnet is a permanent magnet that is second only to absolute zero holmium magnets in magnetism today and is also the most commonly used rare earth magnet. Neodymium iron boron magnets are widely used in electronic products such as hard disks, mobile phones, earphones, and battery powered tools.

In the neodymium iron boron magnet course of working of cylindrical structure, need use material feeding unit, current material feeding unit is at the neodymium iron boron magnet pay-off in-process to the circularity structure, and stability is relatively poor, breaks down easily, leads to the pay-off process of material to break off, has reduced production efficiency, has improved manufacturing cost, and simultaneously, the isolated plant of some cylindrical neodymium iron boron magnet pay-offs, its cost is higher, can't satisfy needs.

Disclosure of Invention

Aiming at the defects of the prior art, the automatic feeding device for the cylindrical neodymium iron boron magnet is high in production efficiency, safe and reliable.

In order to achieve the above object, the present invention provides the following technical solutions.

The utility model provides an automatic feeding of cylindrical neodymium iron boron magnetism iron, includes: the first material storage plate, the second material storage plate, the first material transferring mechanism and the second material transferring mechanism are arranged on the tool frame;

a plurality of first accommodating spaces for accommodating materials are transversely arranged on the first storage plate, a second accommodating space opposite to one end of the first accommodating spaces is transversely arranged on the second storage plate, and a material guide part for guiding materials is arranged at the front end of the second storage plate;

the first material transferring mechanism comprises a material pushing plate arranged at the other end of the first accommodating space and a first telescopic rod driving the material pushing plate to transversely move, and the first telescopic rod extends to drive the material pushing plate to move towards the second accommodating space, so that materials in the first accommodating space enter the second accommodating space;

the second material transferring mechanism comprises an ejection part and a second telescopic rod, the ejection part is arranged at the lower end of the second accommodating space and corresponds to the second accommodating space in quantity, the second telescopic rod drives the ejection part to enter or remove the second accommodating space, the ejection part enters and removes the second accommodating space once, and materials in the second accommodating space move forwards for one lattice and finally slide down from the material guiding part.

After the structure above the adoption, the utility model discloses an automatic feeding of cylindrical neodymium iron boron magnetism iron, compared with the prior art, have following advantage: the feeding device is provided with the first material transferring mechanism and the second material transferring mechanism matched with the first material transferring mechanism, and feeding can be controlled to be opened or closed by controlling the starting and stopping of the first telescopic rod and the second telescopic rod when the feeding device is used, so that the feeding device is simple to operate, convenient to use, simple in structure, long in service life and capable of reducing production cost; in addition, intermittent feeding is continuously carried out, and the production efficiency is improved.

The first accommodating space is arranged along the width direction of the first storage plate, and the second accommodating space is arranged along the width direction of the second storage plate. The first containing space and the second containing space which are arranged are simple in structural design and convenient to use, and meanwhile, the storage quantity and the continuity of feeding are improved.

As an improvement of the utility model, the confession has been seted up on the second storage board the logical groove that liftout portion passed, the second accommodation space sets up with leading to the groove one-to-one, the quantity of liftout portion is corresponding with the quantity that leads to the groove. The liftout portion sets up in second storage plate below to set up the logical groove that supplies liftout portion to pass on the second storage plate, reduced the assembly space.

As an improvement of the utility model, liftout portion upper end is provided with the parallel inclined plane of guide face with guide portion, the inclined plane cooperatees with the material. Set up the inclined plane, the stability of guide when promotion and material contact reduces the both ends landing of liftout portion in-process by liftout portion, effectively avoids the wadding in disorder to appear in the guide.

As an improvement of the utility model, the guide surface of the guide portion extends to the second accommodating space at the most front end of the second material storage plate. Through the improvement, the stability of the material during material guiding is further improved.

As an improvement of the utility model, first storage board and second storage board are all fixed on the frock frame to first storage board sets up on the left frock frame of second storage board. Through the improvement, the connection stability of the device is improved.

As an improvement of the present invention, the first accommodating space is a V-shaped structure. The first containing space with the V-shaped structure plays a certain guiding role for the materials, and the material pushing plate can push the materials in the first containing space conveniently.

As an improvement of the present invention, the material pushing plate is in clearance fit with the first accommodating space. Through the improvement, the running stability of the device is improved.

As an improvement of the utility model, first telescopic link transversely fixes on the frock frame to the removal end and the scraping wings of first telescopic link are connected. Through the improvement, the running stability of the device is improved.

As an improvement of the utility model, the second telescopic link is vertical to be fixed on the frock frame to the removal end and the liftout portion fixed connection of second telescopic link. Through the improvement, the running stability of the device is improved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the first material storage plate and the first material transferring mechanism of the present invention.

Fig. 3 is a top view of a second reservoir plate of the present invention.

Fig. 4 is a schematic structural diagram of the second material storage plate of the present invention.

Fig. 5 is a schematic view of the structure of the ejection part of the present invention.

Fig. 6 is a front view of the present invention.

Shown in the figure: 1. a first reservoir plate; 2. a second storage plate; 21. a second accommodating space; 22. a material guide part; 23. a through groove; 3. a first material transferring mechanism; 31. a material pushing plate; 32. a first telescopic rod; 4. a second material transferring mechanism; 41. a material ejecting part; 411. an inclined portion; 42. a second telescopic rod; 5. a first accommodating space; 6. a tool rack.

Detailed Description

The invention will be further explained with reference to the drawings and the specific embodiments.

Referring to fig. 1-6, the present invention provides an automatic feeding device for cylindrical ndfeb magnet, including: the device comprises a tool frame 6, and a first material storage plate 1, a second material storage plate 2, a first material transfer mechanism 3 and a second material transfer mechanism 4 which are arranged on the tool frame 6;

a plurality of first accommodating spaces 5 for accommodating materials are transversely arranged on the first material storage plate 1, a second accommodating space 21 opposite to one end of each of the plurality of first accommodating spaces 5 is transversely arranged on the second material storage plate 2, and a material guide part 22 for guiding materials is arranged at the front end of the second material storage plate 2;

the first material transferring mechanism 3 comprises a material pushing plate 31 arranged at the other end of the first accommodating space 5 and a first telescopic rod 32 driving the material pushing plate 31 to move transversely, and the first telescopic rod 32 extends to drive the material pushing plate 31 to move towards the second accommodating space 21, so that the material in the first accommodating space 5 enters the second accommodating space 21;

the second material transferring mechanism 4 includes material ejecting portions 41 which are arranged at the lower end of the second accommodating space 21 and correspond to the number of the second accommodating spaces 21, and second telescopic rods 42 which drive the material ejecting portions 41 to ascend and descend, the second telescopic rods 42 drive the material ejecting portions 41 to enter or remove the second accommodating spaces 21, and when the material ejecting portions 41 enter and remove the second accommodating spaces 21 once, the material in the second accommodating spaces 21 moves forward one grid, and finally slides down from the material guiding portions 22.

A plurality of second accommodating spaces 21 are uniformly arranged along the width direction of the second storage plate 2, the second accommodating spaces 21 are arranged in one-to-one correspondence with the through grooves 23, and the number of the material ejecting portions 41 corresponds to the number of the through grooves 23. The upper end of the material ejecting part 41 is provided with an inclined surface 411 parallel to the material guiding surface of the material guiding part 22, and the inclined surface 411 is matched with the material. The material guiding surface of the material guiding portion 22 extends into the second accommodating space 21 at the foremost end of the second material storage plate 2. The first material storage plate 1 and the second material storage plate 2 are both fixed on the tooling frame 6, and the first material storage plate 1 is arranged on the tooling frame 6 on the left side of the second material storage plate 2. The first accommodating space 5 is of a V-shaped structure. The material pushing plate 31 is in clearance fit with the first accommodating space 5. The first telescopic rod 32 is transversely fixed on the tool rack 6, and the moving end of the first telescopic rod 32 is connected with the material pushing plate 31. The second telescopic rod 42 is vertically fixed on the tool rack 6, and the moving end of the second telescopic rod 42 is fixedly connected with the material ejecting part 41.

The working principle is as follows: when the material pushing device is used, a worker transversely places materials in the first accommodating space 5 on the first material storage plate 1 in a non-stacked mode, the first telescopic rod 32 further extends to link the material pushing plate 31 to move towards the second accommodating space 21 along the first accommodating space 5, the material pushing plate 31 abuts against one end face of the materials in the moving process, and the materials are pushed into the second accommodating space 21; further, the ejection part 41 is linked to enter the second accommodating space 21 by extending the second telescopic rod 42, the inclined part 411 at the upper end face of the ejection part 41 is matched with the materials to move the materials one by one from the second accommodating space 21 towards the material guiding part 22, and finally the materials slide down from the material guiding surface of the material guiding part 22, when the second accommodating space 21 is arranged, the number of the second accommodating space 21 is one more than that of the first accommodating space 5, and the second accommodating space 21 which is arranged at the front end of the second material storage plate 2 and does not have the first accommodating space 5 corresponding to the second accommodating space); further feeding the materials in the second accommodating space 21 toward the material guiding part 22; when the material guide device is used, the steps are repeatedly and sequentially executed, so that materials are continuously fed, and a worker can arrange the conveying device at the material guide part 22 to convey the materials to the next processing station. The first material transferring mechanism 3 and the second material transferring mechanism 4 matched with the first material transferring mechanism are arranged, and when the material transferring device is used, the feeding can be controlled to be opened or closed by controlling the starting and stopping of the first telescopic rod 32 and the second telescopic rod 42, so that the operation is simple and the use is convenient; meanwhile, the structure is reliable, the service life is long, and the production cost is reduced; in addition, intermittent feeding is continuously carried out, and the production efficiency is improved. The multiple sets of second accommodating spaces 21 are used in cooperation, so that the storage capacity and the continuity of feeding are improved. The liftout portion 41 is disposed below the second storage plate 2, and the second storage plate 2 is provided with a through groove 22 through which the liftout portion 41 passes, so that an assembly space is reduced. Set up the inclined plane on inclined part 411, promote the stability of inclined part 411 and material guide when contacting, reduce the probability of the ascending in-process material of liftout portion 41 at liftout portion 41 both ends landing, effectively avoid the guide to appear the wadding in disorder. The second material storage plate 2 is provided with a material guide surface 23, so that the stability of material guiding is further improved. The first accommodating space 5 with the V-shaped structure plays a role in guiding the material, so that the material pushing plate 31 can push the material in the first accommodating space 5 conveniently.

Above only the utility model discloses an it is preferred embodiment, the utility model discloses a scope of protection not only limits in above-mentioned embodiment, and the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides an automatic feeding of cylindrical neodymium iron boron magnetism iron, its characterized in that includes: the device comprises a tool frame (6), and a first material storage plate (1), a second material storage plate (2), a first material transfer mechanism (3) and a second material transfer mechanism (4) which are arranged on the tool frame (6);

a plurality of first accommodating spaces (5) used for accommodating materials are transversely arranged on the first material storage plate (1), a second accommodating space (21) opposite to one end of the first accommodating spaces (5) is transversely arranged on the second material storage plate (2), and a material guide part (22) used for guiding materials is arranged at the front end of the second material storage plate (2);

the first material transferring mechanism (3) comprises a material pushing plate (31) arranged at the other end of the first accommodating space (5) and a first telescopic rod (32) driving the material pushing plate (31) to move transversely, and the first telescopic rod (32) extends to drive the material pushing plate (31) to move towards the second accommodating space (21), so that materials in the first accommodating space (5) enter the second accommodating space (21);

the second material transferring mechanism (4) comprises an ejection part (41) which is arranged at the lower end of the second accommodating space (21) and corresponds to the second accommodating space (21) in quantity, and a second telescopic rod (42) which drives the ejection part (41) to ascend and descend, wherein the second telescopic rod (42) drives the ejection part (41) to enter or remove the second accommodating space (21), and the ejection part (41) enters and removes the second accommodating space once, and materials in the second accommodating space (21) move forwards for one lattice and finally slide down through the material guiding part (22).

2. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the first accommodating spaces (5) are arranged along the width direction of the first material storage plate (1), and the second accommodating spaces (21) are arranged along the width direction of the second material storage plate (2).

3. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the second material storage plate (2) is provided with through grooves (23) for the ejection portions (41) to penetrate through, the second accommodating spaces (21) and the through grooves (23) are arranged in a one-to-one correspondence mode, and the number of the ejection portions (41) corresponds to the number of the through grooves (23).

4. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the upper end of the material ejecting part (41) is provided with an inclined surface (411) parallel to the material guiding surface of the material guiding part (22), and the inclined surface (411) is matched with the material.

5. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 4, characterized in that: the material guiding surface of the material guiding part (22) extends into the second accommodating space (21) at the foremost end of the second material storage plate (2).

6. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the first material storage plate (1) and the second material storage plate (2) are fixed on the tool frame (6), and the first material storage plate (1) is arranged on the tool frame (6) on the left side of the second material storage plate (2).

7. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the first accommodating space (5) is of a V-shaped structure.

8. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the material pushing plate (31) is in clearance fit with the first accommodating space (5).

9. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the first telescopic rod (32) is transversely fixed on the tool rack (6), and the moving end of the first telescopic rod (32) is connected with the material pushing plate (31).

10. The automatic feeding device of cylindrical neodymium iron boron magnet according to claim 1, characterized in that: the second telescopic rod (42) is vertically fixed on the tool rack (6), and the moving end of the second telescopic rod (42) is fixedly connected with the material ejecting part (41).

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