CN215796854U - Ferrite core is with device of arranging with adjustable size - Google Patents

Abstract

The utility model discloses a size-adjustable distribution device for ferrite cores, which is used for dredging and distributing the ferrite cores; the bearing frame is arranged in a U-shaped structure, and the top surface of the bearing frame is connected to the top end of the hopper frame in a penetrating manner; the inner parts of the left side and the right side of the bearing frame are respectively provided with a rotary guide rod in a rotating way through a bearing; the method comprises the following steps: the left side and the right side above the inside of the feed hopper frame are both fixedly provided with dredging mechanisms; the distribution mechanism is preset at the center position inside the bearing frame, and the left side and the right side of the top end of the distribution mechanism are connected to the bottom end of the locking rod in a sliding penetrating mode; wherein, the bottom surface of transmission device is fixed with supporting platform. This ferrite core with adjustable size is with device of arranging realizes the mediation unloading at first through the feeder hopper frame to arrange the ferrite core through the mechanism of arranging of moving opposite direction and the board of arranging, carry out the ejection of compact through the transmission device that intermittent type removed simultaneously.

Description

Ferrite core is with device of arranging with adjustable size

Technical Field

The utility model relates to the technical field of ferrite cores, in particular to a size-adjustable arrangement device for ferrite cores.

Background

The ferrite magnetic core is a high-frequency magnetic conductive material, the principle of which is similar to that of a silicon steel sheet, and is mainly used in a high-frequency environment and used as a main component of a high-frequency transformer such as a switching power supply, a line output transformer, a high-frequency magnetic ring (for interference resistance) and the like.

And present most ferrite core is in the course of working, and a plurality of ferrite core base are evenly arranged on holding the fever board usually, then send into the sintering furnace in, and traditional mode of arranging adopts manual work, but the artifical inefficiency that arranges leads to people's work slow, increases people's economic cost to and some cloth arranging machines inconvenient taking out after arranging the completion, can shorten work efficiency greatly like this, the qualification rate of arranging simultaneously is also comparatively low.

We therefore propose an arrangement for ferrite cores that is adjustable in size so as to solve the problems set out above.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a size-adjustable ferrite core arranging device, which solves the problems that in the processing process of most ferrite cores in the market, generally, a plurality of ferrite core blanks are uniformly arranged on a burning bearing plate and then are sent into a sintering furnace, the traditional arranging mode adopts manual operation, but the manual arranging efficiency is low, so that the work of people is slow, the economic cost of people is increased, and some arranging machines are inconvenient to take out after the arrangement is finished, so that the work efficiency is greatly shortened, and the arrangement qualification rate is low.

In order to achieve the purpose, the utility model provides the following technical scheme: an arrangement device for ferrite cores with adjustable size is used for dredging and arranging the ferrite cores;

the bearing frame is arranged in a U-shaped structure, and the top surface of the bearing frame is connected to the top end of the hopper frame in a penetrating manner;

the inner parts of the left side and the right side of the bearing frame are respectively provided with a rotating guide rod in a rotating way through a bearing, and the inner bottom surface of the bearing frame is fixedly provided with a transmission mechanism;

the method comprises the following steps:

the left side and the right side above the inside of the hopper frame are both fixedly provided with dredging mechanisms, the bottom surfaces of the inner sides of the dredging mechanisms are both connected to the top end of the transmission rod in a penetrating and rotating mode through bearings, and the bottom surfaces of the transmission rods are hinged with dredging rotating rods;

the distribution mechanism is preset at the center position inside the bearing frame, and the left side and the right side of the top end of the distribution mechanism are connected to the bottom end of the locking rod in a sliding penetrating mode;

the bottom surface of the transmission mechanism is fixedly provided with a supporting platform, the inside of the supporting platform is transversely provided with a driving rod in a penetrating mode through a bearing, and the left end of the driving rod is connected to the outer wall of the bottom surface of the rotating guide rod in the bearing frame in a meshing mode through a bevel gear.

Preferably, the inside feed hopper frame of load-bearing frame sets up for the awl font structure of invering, and the bottom surface laminating of the inside mediation bull stick of feed hopper frame connects in the outer wall of feed hopper frame to the outer wall of mediation bull stick and the feed hopper frame left and right sides is the slope column structure setting, dredges feed hopper frame through the mediation bull stick.

Preferably, the bottom surface level of feed hopper frame is greater than the top surface level setting that bears the weight of the frame, and the vertical central axis symmetric distribution setting about the feed hopper frame of the mediation mechanism of the inside left and right sides of feed hopper frame to the one-to-one distribution setting between mediation mechanism and transfer line and the mediation bull stick, the top outer wall of the inside transfer line of mediation mechanism passes through the drive belt meshing in addition and connects in the top outer wall of rotatory guide arm, drives the inside transfer line of mediation mechanism through rotatory guide arm and rotates.

Preferably, both ends all rotate through the bearing and are provided with drive gear about transmission mechanism below supporting platform, and drive gear's outer wall meshing connects in the outer wall of conveying track to supporting platform's bottom surface left side is rotated through the bearing and is provided with the thumb wheel, and supporting platform left end drive gear's the place ahead fixedly connected with sheave in addition drives thumb wheel and sheave through the actuating lever and rotates.

Preferably, the transmission gears are symmetrically distributed about a vertical central axis of the supporting platform, the front of the poking wheel on the top surface of the supporting platform is connected to the outer wall of the left end of the driving rod through a conical gear in a meshed mode, the poking wheel is connected to the inner portion of a grooved wheel in front of the transmission gears in a penetrating and meshed mode, and the grooved wheel is driven to rotate intermittently through rotation of the poking wheel.

Preferably, the inside of the arrangement mechanism slides and penetrates through the arrangement plate, the outer walls of the left side and the right side of the arrangement mechanism are fixedly connected to the middle of the rotary guide rod through the hinged main crankshaft rod, the outer walls of the left end and the right end of the arrangement plate are fixedly connected to the lower portion of the middle of the rotary guide rod through the hinged auxiliary crankshaft rod, and the arrangement plate is driven to move through the auxiliary crankshaft rod.

Preferably, the arrangement mechanism and the arrangement plate are in sliding connection with each other, the arrangement mechanism is parallel to the arrangement plate, and the arrangement mechanism and the arrangement plate are opposite in moving direction, so that the permanent magnet cores can fall down when the arrangement mechanism and the arrangement plate are overlapped.

Compared with the prior art, the utility model has the beneficial effects that: according to the distribution device for the ferrite cores with the adjustable sizes, dredging and blanking are firstly achieved through the feed hopper frame, the ferrite cores are distributed through the distribution mechanism and the distribution plate which are opposite in moving direction, and meanwhile, discharging is conducted through the intermittent moving transmission mechanism;

1. the ferrite magnetic cores are firstly put in through a feed hopper frame on the top surface of the bearing frame, and the dredging rotating rod driven by a transmission belt in the dredging mechanism rotates to prevent the ferrite magnetic cores from being blocked in the feed hopper frame and falling to the inside of the arrangement mechanism through the ferrite magnetic cores in the feed hopper frame;

2. the arrangement mechanism at the inner end and the arrangement plate are driven to move in the direction through the crankshaft rod connected with the rotary guide rod, so that the ferrite magnetic core falls to the top surface of the transmission crawler through the internal regular opening, and intermittent conveying is carried out through the poking wheel and the grooved pulley.

Drawings

FIG. 1 is a schematic cross-sectional view of the present invention;

FIG. 2 is a schematic structural view of the front section of the dredging mechanism of the present invention;

FIG. 3 is a schematic view of a rotating guide bar mounting arrangement of the present invention;

FIG. 4 is a schematic view of the driving rod mounting structure of the present invention;

FIG. 5 is a schematic cross-sectional view of a support platform according to the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 1 according to the present invention.

In the figure: 1. a load-bearing frame; 2. a hopper frame; 3. rotating the guide rod; 4. a transport mechanism; 5. a dredging mechanism; 6. a transmission rod; 7. dredging the rotating rod; 8. an arrangement mechanism; 9. a lock lever; 10. a support platform; 11. a drive rod; 12. a transmission gear; 13. a conveying crawler; 14. a poking wheel; 15. a grooved wheel; 16. a cloth arranging plate; 17. a main crankshaft rod; 18. an auxiliary crankshaft rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides the following technical solutions: an arrangement device for ferrite cores with adjustable size is used for dredging and arranging the ferrite cores;

the bearing frame 1 is arranged in a U-shaped structure, and the top surface of the bearing frame 1 is connected with the top end of the hopper frame 2 in a penetrating manner; the inner parts of the left side and the right side of the bearing frame 1 are respectively provided with a rotating guide rod 3 through a bearing in a rotating way, and the inner bottom surface of the bearing frame 1 is fixedly provided with a transmission mechanism 4; the method comprises the following steps:

the left side and the right side of the upper part inside the hopper frame 2 are fixedly provided with dredging mechanisms 5, the bottom surfaces of the inner sides of the dredging mechanisms 5 are connected to the top end of a transmission rod 6 in a penetrating and rotating mode through bearings, and the bottom surface of the transmission rod 6 is hinged with a dredging rotating rod 7;

the arrangement mechanism 8 is preset at the center position inside the bearing frame 1, and the left side and the right side of the top end of the arrangement mechanism 8 are connected to the bottom end of the locking rod 9 in a sliding and penetrating manner; wherein, the bottom surface of transmission device 4 is fixed and is provided with supporting platform 10, and the inside of supporting platform 10 transversely runs through the bearing and is provided with actuating lever 11, and the left end of actuating lever 11 passes through the conical gear meshing and connects in the inside bottom surface outer wall of rotatory guide arm 3 of load-bearing frame 1.

The inside feed hopper frame 2 of bearing frame 1 sets up for the awl font structure of invering, and the bottom surface laminating of the inside mediation bull stick 7 of feed hopper frame 2 is connected in the outer wall of feed hopper frame 2 to the outer wall of mediation bull stick 7 and the feed hopper frame 2 left and right sides is the slope column structure setting. The bottom surface level of feed hopper frame 2 is greater than the top surface level setting that bears frame 1, and the vertical central axis symmetric distribution setting about feed hopper frame 2 of the mediation mechanism 5 of the inside left and right sides of feed hopper frame 2 to between mediation mechanism 5 and transfer line 6 and the mediation bull stick 7 one-to-one distribute the setting, the top outer wall of 5 inside transfer lines 6 of mediation mechanism passes through the drive belt meshing in the top outer wall of rotating guide 3 moreover.

As shown in fig. 1-2, after the feeding hopper frame 2 is supported by the carrying frame 1, the rotating guide rods 3 on the left and right sides of the carrying frame 1 drive the transmission rod 6 penetrating through the inside of the dredging mechanism 5 to rotate, and meanwhile, the transmission rod 6 drives the dredging rotating rod 7 with the hinged bottom end to rotate on the top surface of the feeding hopper frame 2 in a fitting manner, so as to dredge the ferrite core.

A transmission gear 12 is rotatably arranged at the left end and the right end of a support platform 10 below the transmission mechanism 4 through bearings, the outer wall of the transmission gear 12 is meshed and connected with the outer wall of a transmission crawler 13, a poking wheel 14 is rotatably arranged at the left side of the bottom surface of the support platform 10 through a bearing, and a grooved wheel 15 is fixedly connected in front of the transmission gear 12 at the left end of the support platform 10; the transmission gears 12 are symmetrically distributed about a vertical central axis of the supporting platform 10, the front of the poking wheel 14 on the top surface of the supporting platform 10 is meshed with the outer wall of the left end of the driving rod 11 through a conical gear, and the poking wheel 14 is meshed with the inner part of a grooved wheel 15 in front of the transmission gears 12 in a penetrating and meshing mode.

As shown in fig. 4 to 5, the driving rod 11 penetrating the supporting platform 10 drives the rotation guide rod 3 to rotate, and the outer wall of the driving rod 11 drives the sheave 15 and the transmission gear 12 to rotate while rotating the dial 14 engaged with the bevel gear, so as to drive the transmission crawler 13 engaged with the outer wall to rotate.

A cloth arranging plate 16 penetrates through the inside of the cloth arranging mechanism 8 in a sliding mode, the upper portions of the outer walls of the left side and the right side of the cloth arranging mechanism 8 are fixedly connected to the middle of the rotary guide rod 3 through hinged main crankshaft rods 17, and the outer walls of the left end and the right end of the cloth arranging plate 16 are fixedly connected to the lower portion of the middle of the rotary guide rod 3 through hinged auxiliary crankshaft rods 18; the arrangement mechanism 8 and the arrangement plate 16 are mutually attached in a sliding connection mode, the transverse central axis of the arrangement mechanism 8 and the transverse central axis of the arrangement plate 16 are arranged in parallel, and the arrangement mechanism 8 and the arrangement plate 16 are arranged in the opposite moving directions.

As shown in fig. 1 and 3, after the main crankshaft 17 and the auxiliary crankshaft 18 on the upper and lower sides are driven to rotate by the rotating guide rod 3, the main crankshaft 17 drives the arranging mechanism 8 and the auxiliary crankshaft 18 drives the arranging plate 16 to move, so that the moving directions between the arranging mechanism 8 and the arranging plate 16 are opposite, and the ferrite core falls when the arranging mechanism 8 and the arranging plate 16 are overlapped.

The working principle is as follows: before using the arranging device for the ferrite magnetic cores with adjustable size, the overall situation of the device needs to be checked firstly to determine that the device can work normally, as shown in fig. 1-6, firstly, dredging and blanking are realized by the feed hopper frame 2, the ferrite magnetic cores are arranged by the arranging mechanism 8 and the arranging plate 16 which move in opposite directions, the main crankshaft 17 and the auxiliary crankshaft 18 connected with the rotary guide rod 3 drive the arranging mechanism 8 and the arranging plate 16 at the inner end to move in directions, and the sheave 15 driven by the poking wheel 14 and the conveying crawler 13 drive the ferrite magnetic cores to perform intermittent conveying.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the utility model can be made, and equivalents and modifications of some features of the utility model can be made without departing from the spirit and scope of the utility model.

Claims (7)

1. An arrangement device for ferrite cores with adjustable size is used for dredging and arranging the ferrite cores;

the bearing frame (1) is arranged in a U-shaped structure, and the top surface of the bearing frame (1) is connected with the top end of the feed hopper frame (2) in a penetrating manner;

the inner parts of the left side and the right side of the bearing frame (1) are respectively provided with a rotating guide rod (3) through a bearing in a rotating way, and the inner bottom surface of the bearing frame (1) is fixedly provided with a transmission mechanism (4);

it is characterized by comprising:

the left side and the right side of the upper part inside the hopper frame (2) are fixedly provided with dredging mechanisms (5), the bottom surfaces of the inner sides of the dredging mechanisms (5) are respectively connected to the top end of the transmission rod (6) in a penetrating and rotating mode through bearings, and the bottom surface of the transmission rod (6) is hinged with a dredging rotating rod (7);

the distribution mechanism (8) is preset at the center position inside the bearing frame (1), and the left side and the right side of the top end of the distribution mechanism (8) are connected to the bottom end of the locking rod (9) in a sliding and penetrating mode;

the bottom surface of the transmission mechanism (4) is fixedly provided with a supporting platform (10), the inside of the supporting platform (10) is transversely provided with a driving rod (11) in a penetrating mode through a bearing, and the left end of the driving rod (11) is meshed with the outer wall of the bottom surface of the rotating guide rod (3) in the bearing frame (1) through a bevel gear.

2. An arrangement for a size adjustable ferrite core according to claim 1, wherein: the feed hopper frame (2) inside the bearing frame (1) is arranged in a cone-shaped structure for inversion, the bottom surface of the dredging rotating rod (7) inside the feed hopper frame (2) is attached to the outer wall of the feed hopper frame (2), and the dredging rotating rod (7) and the outer walls of the left side and the right side of the feed hopper frame (2) are arranged in an inclined structure.

3. An arrangement for a size adjustable ferrite core according to claim 2, wherein: the bottom surface level of feed hopper frame (2) is greater than the top surface level setting that bears frame (1), and the vertical center axis symmetric distribution setting about feed hopper frame (2) of dredge mechanism (5) of the inside left and right sides of feed hopper frame (2) to dredge mechanism (5) and transfer line (6) and dredge bull stick (7) between the one-to-one distribution setting, and the top outer wall of dredge mechanism (5) inside transfer line (6) passes through the drive belt meshing and connects in the top outer wall of rotating guide (3) moreover.

4. An arrangement for a size adjustable ferrite core according to claim 1, wherein: both ends all are provided with drive gear (12) through the bearing rotation about transmission mechanism (4) below supporting platform (10), and the outer wall meshing of drive gear (12) is connected in the outer wall of conveying track (13) to the bottom surface left side of supporting platform (10) is provided with thumb wheel (14) through the bearing rotation, and supporting platform (10) left end drive gear's the place ahead fixedly connected with sheave (15) of (12) moreover.

5. An arrangement for a size adjustable ferrite core according to claim 4, wherein: the transmission gears (12) are symmetrically distributed about a vertical central axis of the supporting platform (10), the front of the poking wheel (14) on the top surface of the supporting platform (10) is connected to the outer wall of the left end of the driving rod (11) through conical gears in a meshed mode, and the poking wheel (14) is connected to the inner portion of a front grooved wheel (15) of the transmission gears (12) in a penetrating and meshed mode.

6. An arrangement for a size adjustable ferrite core according to claim 1, wherein: the cloth arranging mechanism is characterized in that a cloth arranging plate (16) penetrates through the inside of the cloth arranging mechanism (8) in a sliding mode, the outer walls of the left side and the right side of the cloth arranging mechanism (8) are fixedly connected to the middle of the rotary guide rod (3) through hinged main crankshaft rods (17), and the outer walls of the left end and the right end of the cloth arranging plate (16) are fixedly connected to the lower portion of the middle of the rotary guide rod (3) through hinged auxiliary crankshaft rods (18).

7. An arrangement for a size adjustable ferrite core according to claim 6, wherein: the cloth arranging mechanism (8) and the cloth arranging plate (16) are mutually attached in a sliding connection mode, the transverse central axis of the cloth arranging mechanism (8) and the transverse central axis of the cloth arranging plate (16) are arranged in parallel, and the moving directions of the cloth arranging mechanism (8) and the cloth arranging plate (16) are opposite.

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