CN219040238U - Manganese zinc ferrite position rotation equipment - Google Patents

Abstract

The utility model discloses manganese-zinc ferrite position rotating equipment, which comprises a manganese-zinc ferrite rotating position assembly, a transmission belt assembly and a manganese-zinc ferrite absorbing assembly, wherein the manganese-zinc ferrite rotating position assembly comprises a rotary cylinder, an absorbing rotating member arranged on a rotary support of the rotary cylinder, the absorbing rotating member comprises an absorbing shell, a telescopic cylinder arranged in the absorbing shell, a magnet placing plate arranged at the output end of the telescopic cylinder and a magnet block arranged at one side of the magnet placing plate; the manganese-zinc ferrite absorbing assembly is used for absorbing and placing a plurality of manganese-zinc ferrites on the manganese-zinc ferrite rotating position assembly, the telescopic cylinder in the manganese-zinc ferrite rotating position assembly extends out, a magnet block of the telescopic cylinder is propped against one side in the absorbing shell, the manganese-zinc ferrites are magnetically absorbed outside the absorbing shell, the absorbing shell is rotated 180 degrees by the rotary cylinder, the manganese-zinc ferrites are located on the driving belt assembly, the telescopic cylinder contracts, the manganese-zinc ferrites fall on the driving belt assembly, and the manganese-zinc ferrite is rotated in position.

Description

Manganese zinc ferrite position rotation equipment

Technical Field

The utility model relates to the field of small manganese-zinc ferrite production, in particular to manganese-zinc ferrite position rotating equipment.

Background

The small Mn-Zn ferrite is shown in figure 1, is mainly a product surface shape with a center pillar in the design, has smaller dimensional specification tolerance, and is suitable for automotive electronic devices with stricter tolerance requirements.

When the small manganese-zinc ferrite is pressed and manufactured, the side of the small manganese-zinc ferrite with the center pillar faces downwards, however, the side of the small manganese-zinc ferrite with the center pillar faces upwards in the sintering process of the small manganese-zinc ferrite, and the side of the small manganese-zinc ferrite with the center pillar faces downwards in the sintering process of the small manganese-zinc ferrite, the size difference after sintering is larger, so that the size difference exceeds the formulated specification, namely the product cannot be normally shipped; therefore, the small manganese zinc ferrite needs to be turned over for 180 degrees, so that the side containing the center pillar faces upwards to be sintered, and the back shrinkage rate of the small manganese zinc ferrite in the later stage of the manufacturing process meets the specification.

However, no special equipment is used for turning over the small manganese-zinc ferrite for 180 degrees in the existing manufacturing process, the small manganese-zinc ferrite needs to be turned over manually, labor is consumed, and the working efficiency is low.

Thus, there is a need for an apparatus that can rotate the position of small manganese zinc ferrite.

Disclosure of Invention

In view of this, the present utility model aims to provide a rotating device capable of magnetically rotating the manganese zinc ferrite position.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the utility model provides a manganese zinc ferrite position rotation equipment, includes manganese zinc ferrite rotation position subassembly, sets up the drive belt subassembly of position rotation subassembly below sets up manganese zinc ferrite of position rotation subassembly top absorbs the subassembly, manganese zinc ferrite rotation position subassembly includes the revolving cylinder, fixed mounting absorb the rotation member on the revolving rack of revolving cylinder, absorb the rotation member and include and absorb the shell, fixed mounting is in absorb the inside telescopic cylinder of shell, fixed mounting is in the magnet of telescopic cylinder output places the board, fixed mounting is in magnet piece that board one side was placed to magnet.

Preferably, the magnet placement plate and the magnet block are fixed by bolts.

Preferably, the driving belt assembly comprises a driving belt for driving the manganese-zinc ferrite, and a manganese-zinc ferrite limit bar arranged above the driving belt.

Preferably, the manganese zinc ferrite absorbing component comprises a transverse telescopic cylinder, a vertical telescopic cylinder arranged at the output end of the transverse telescopic cylinder, a longitudinal telescopic cylinder arranged at the output end of the vertical telescopic cylinder, and an absorbing piece fixedly arranged at the output end of the longitudinal telescopic cylinder.

Preferably, the sucking piece is provided with a plurality of sucking discs for sucking the Mn-Zn ferrite.

The utility model has the technical effects that: according to the utility model, the manganese-zinc ferrite absorbing assembly is used for absorbing and placing a plurality of manganese-zinc ferrites on the manganese-zinc ferrite rotating position assembly, the telescopic air cylinder in the manganese-zinc ferrite rotating position assembly extends out, so that the magnet block of the telescopic air cylinder is propped against one side in the absorbing shell, the manganese-zinc ferrites are magnetically absorbed outside the absorbing shell, the rotating air cylinder rotates the absorbing shell by 180 degrees, the manganese-zinc ferrites are positioned on the driving belt assembly, then the telescopic air cylinder contracts, the magnet block is far away from one side in the absorbing shell, and the manganese-zinc ferrites fall on the driving belt assembly, so that the manganese-zinc ferrites can rotate in position.

Drawings

FIG. 1 is a diagram showing the structure of a manganese zinc ferrite product;

FIG. 2 is a block diagram of a Mn-Zn ferrite position rotation apparatus of the present utility model;

FIG. 3 is an internal structural view of the Mn-Zn ferrite rotational position assembly of FIG. 1;

fig. 4 is a diagram of the operation of the manganese zinc ferrite rotational position assembly of fig. 1.

Detailed Description

The following detailed description of the utility model is provided in connection with the accompanying drawings to facilitate understanding and grasping of the technical scheme of the utility model.

In this embodiment, it should be understood that the directions or positional relationships indicated by the terms "middle", "upper", "lower", "top", "right", "left", "upper", "back", "middle", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of description of the present utility model, and do not indicate or imply that the apparatus or elements referred to must have a specific direction, be configured and operated in a specific direction, and thus should not be construed as limiting the present utility model.

In this embodiment, if not specifically described, the members may be connected or fixed by bolts, pins, or the like, which are commonly used in the prior art, and therefore, the details thereof will not be described in this embodiment.

The manganese zinc ferrite position rotating equipment comprises a manganese zinc ferrite rotating position assembly 1 and a driving belt assembly 2 arranged below the manganese zinc ferrite rotating position assembly 1, wherein the driving belt assembly 2 comprises a driving belt 21 for driving manganese zinc ferrite, and manganese zinc ferrite limit strips 22 are arranged above the driving belt 21. Specifically, the driving belt 21 conveys the manganese-zinc ferrite to the next station, the driving belt 21 is provided with two limiting strips 22, and a gap between the two limiting strips 22 is slightly larger than the manganese-zinc ferrite, so that the manganese-zinc ferrite falls onto the driving belt 21 and is guided by the two limiting strips 22 to be arranged into a straight line. The manganese zinc ferrite absorbing component 3 is arranged above the position rotating component 1, the manganese zinc ferrite absorbing component 3 comprises a transverse telescopic cylinder 31, a vertical telescopic cylinder 32 arranged at the output end of the transverse telescopic cylinder 31, a longitudinal telescopic cylinder 33 arranged at the output end of the vertical telescopic cylinder 32 and an absorbing piece 34 fixedly arranged at the output end of the longitudinal telescopic cylinder 33. The suction piece 34 is provided with a plurality of suction cups 341 for sucking the manganese zinc ferrite. In the process of absorbing the manganese zinc ferrite, the transverse telescopic cylinder 31, the vertical telescopic cylinder 32 and the longitudinal telescopic cylinder 33 are sequentially stretched, so that the absorbing piece 34 enters a pressing cavity of the manganese zinc ferrite pressing machine, a plurality of sucking discs 341 of the absorbing piece 34 correspondingly absorb the manganese zinc ferrite, then the longitudinal telescopic cylinder 33, the vertical telescopic cylinder 32 and the transverse telescopic cylinder 31 are sequentially recovered, and the manganese zinc ferrite is moved to the absorbing rotary member 12, including the absorbing shell 121 and is absorbed.

As shown in fig. 3 to 4, the manganese zinc ferrite rotary position assembly 1 includes a rotary cylinder 11, and a suction rotary member 12 fixedly mounted on a rotary bracket of the rotary cylinder 11. The sucking rotary member 12 includes a sucking housing 121, a telescopic cylinder 122 fixedly installed inside the sucking housing 121, a magnet placing plate 123 fixedly installed at an output end of the telescopic cylinder 122, and a magnet block 124 fixedly installed at one side of the magnet placing plate 123. The magnet placement plate 123 and the magnet block 124 are fixed by bolts. Specifically, the telescopic cylinder 122 extends to make the magnet block 124 prop against one side of the inside of the suction housing 121, the manganese-zinc ferrite is magnetically attracted outside the suction housing 121, the rotary cylinder 11 rotates the suction housing 121 by 180 ° and the manganese-zinc ferrite is located on the driving belt assembly 2, then the telescopic cylinder 122 contracts, the magnet block 124 is far away from one side of the inside of the suction housing 121, and the manganese-zinc ferrite falls on the driving belt assembly 2.

Working principle: when the manganese zinc ferrite is pressed and produced, one surface of the manganese zinc ferrite containing a center pillar faces downwards, and the transverse telescopic cylinder 31, the vertical telescopic cylinder 32 and the longitudinal telescopic cylinder 33 of the manganese zinc ferrite absorbing assembly 3 sequentially extend, so that absorbing pieces 34 enter a pressing cavity of a manganese zinc ferrite pressing machine to absorb a plurality of manganese zinc ferrites.

After that, the longitudinal telescopic cylinder 33 and the transverse telescopic cylinder 31 are sequentially reset, and the manganese-zinc-ferrite is moved to the outside of the suction housing 121, and at this time, the surface of the manganese-zinc-ferrite containing the center pillar is downward in contact with the outside of the suction housing 121; the Mn-Zn ferrite is sucked outside the suction housing 121, the suction piece 34 stops suction, and the vertical telescopic cylinder 32 is reset.

Finally, the rotary cylinder 11 rotates the suction housing 121 by 180 degrees, the suction housing 121 stops magnetically sucking the manganese-zinc ferrite, the manganese-zinc ferrite falls onto the driving belt 21, and at the moment, one surface of the manganese-zinc ferrite containing the center pillar is turned upwards, so that the turning of the manganese-zinc ferrite is realized.

The utility model has the technical effects that: according to the utility model, the manganese-zinc ferrite absorbing assembly is used for absorbing and placing a plurality of manganese-zinc ferrites on the manganese-zinc ferrite rotating position assembly, the telescopic air cylinder in the manganese-zinc ferrite rotating position assembly extends out, so that the magnet block of the telescopic air cylinder is propped against one side in the absorbing shell, the manganese-zinc ferrites are magnetically absorbed outside the absorbing shell, the rotating air cylinder rotates the absorbing shell by 180 degrees, the manganese-zinc ferrites are positioned on the driving belt assembly, then the telescopic air cylinder contracts, the magnet block is far away from one side in the absorbing shell, and the manganese-zinc ferrites fall on the driving belt assembly, so that the manganese-zinc ferrites can rotate in position.

Of course, the above is only a typical example of the utility model, and other embodiments of the utility model are also possible, and all technical solutions formed by equivalent substitution or equivalent transformation fall within the scope of the utility model claimed.

Claims (5)

1. The utility model provides a manganese zinc ferrite position rotation equipment, includes manganese zinc ferrite rotation position subassembly, sets up the drive belt subassembly of position rotation subassembly below, set up manganese zinc ferrite of position rotation subassembly top absorbs subassembly, its characterized in that: the manganese zinc ferrite rotation position component comprises a rotary cylinder, a suction rotation component fixedly installed on a rotary support of the rotary cylinder, the suction rotation component comprises a suction shell, a telescopic cylinder fixedly installed inside the suction shell, a magnet placement plate fixedly installed at the output end of the telescopic cylinder and a magnet block fixedly installed at one side of the magnet placement plate.

2. A manganese zinc ferrite positional rotation apparatus as defined in claim 1, wherein: the magnet placing plate and the magnet block are fixed through bolts.

3. A manganese zinc ferrite positional rotation apparatus as defined in claim 1, wherein: the driving belt assembly comprises a driving belt for driving the Mn-Zn ferrite, and Mn-Zn ferrite limit bars arranged above the driving belt.

4. A manganese zinc ferrite positional rotation apparatus as defined in claim 1, wherein: the manganese zinc ferrite absorbing component comprises a transverse telescopic cylinder, a vertical telescopic cylinder arranged at the output end of the transverse telescopic cylinder, a longitudinal telescopic cylinder arranged at the output end of the vertical telescopic cylinder and absorbing pieces fixedly arranged at the output end of the longitudinal telescopic cylinder.

5. A manganese zinc ferrite positional rotation apparatus as defined in claim 4, wherein: the sucking piece is provided with a plurality of sucking discs for sucking the Mn-Zn ferrite.

Images