CN215451160U - Magnetic core shell loading machine - Google Patents

Abstract

The utility model discloses a magnetic core shell loading machine which comprises a workbench, wherein a first vibrating disk is fixedly connected to any one side position of the upper surface of the workbench, a second vibrating disk is fixedly connected to one side position of the upper surface of the workbench, which is far away from the first vibrating disk, a fixed support frame is fixedly connected between the first vibrating disk and the second vibrating disk, the position of the fixed support frame is fixedly connected with a magnetic core assembling device, and discharge ports of the first vibrating disk and the second vibrating disk are aligned to the fixed support frame. The utility model can ensure that the magnetic core assembly mechanization degree is high, the assembly efficiency is greatly improved, and the labor cost is effectively reduced.

Description

Magnetic core shell loading machine

Technical Field

The utility model relates to the technical field of magnetic core assembly, in particular to a magnetic core shell assembling machine.

Background

Magnetic core: magnetic core refers to a sintered magnetic metal oxide composed of various iron oxide mixtures.

In the prior art, the magnetic core needs manual assembly during assembly, so that the assembly efficiency is poor, and meanwhile, hands are hurt during manual assembly, so that the magnetic core is not suitable for long-time assembly.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of poor magnetic core assembly efficiency.

In order to solve the technical problems, the utility model adopts a technical scheme that: the utility model provides a magnetic core dress shell machine, comprises a workbench, the first vibration dish of the arbitrary one side position fixedly connected with of workstation upper surface, first vibration dish one side position fixedly connected with second vibration dish is kept away from to the workstation upper surface, the workstation upper surface is located fixedly connected with fix support frame between first vibration dish and the second vibration dish, fix support frame position fixedly connected with magnetic core assembly quality, fix support frame is aimed at to the discharge gate of first vibration dish and second vibration dish.

Preferably, magnetic core assembly quality includes first cylinder, first cylinder is close to first vibration dish one side fixed connection with the fixed bolster, the flexible end of first cylinder passes through the first revolving cylinder of backup pad fixedly connected with, the drive end position rotation of first revolving cylinder is connected with the second revolving cylinder, the second revolving cylinder drive end position rotation is connected with first work arm lock, and first cylinder drives first revolving cylinder and goes up and down, and first revolving cylinder drives the second revolving cylinder rotation, and the second revolving cylinder drives first work arm lock turn-over.

Preferably, the middle position of the upper surface of the fixed support frame is fixedly connected with a fourth cylinder, the telescopic end position of the fourth cylinder is fixedly connected with an assembling ring, and the fourth cylinder drives the assembling ring to extend out of a station.

Preferably, the upper surface of the fixed support frame is close to a second vibration disc position fixedly connected with a second cylinder, the telescopic end of the second cylinder is fixedly connected with a third cylinder, the telescopic end of the third cylinder is fixedly connected with a second working clamping arm, the second cylinder drives the third cylinder to do horizontal linear motion, and the third cylinder drives the second working clamping arm to do vertical linear motion.

Preferably, the working end positions of the first working clamping arm and the second working clamping arm are fixedly connected with a clamping ring.

Preferably, workstation and fixed bolster are manganese steel material, first vibration dish discharge gate position fixedly connected with holding ring, second vibration dish discharge gate position fixedly connected with standing groove.

The utility model has the following beneficial effects:

the magnetic core is installed and assembled through mechanical equipment, the assembling efficiency is high, labor waste caused by excessive labor force intervening and assembling is avoided, the production cost is reduced, the equipment is only available, and the operation is simple and convenient.

Drawings

FIG. 1 is a left side elevational view of a magnetic core shell loader of the present invention;

FIG. 2 is a right front view of a magnetic core shell loader of the present invention;

fig. 3 is a top view of a magnetic core shell loader according to the present invention.

In the figure: 101. a first vibratory pan; 102. a positioning ring; 103. a first cylinder; 104. a first rotary cylinder; 105. a second rotary cylinder; 106. a first working clamp arm; 107. a second vibratory pan; 108. a placement groove; 109. a second cylinder; 110. a third cylinder; 111. a second working clamp arm; 112. a fourth cylinder; 113. clipping a ring; 114. assembling a ring; 115. a work table; 116. and fixing the support frame.

Detailed Description

The following detailed description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings, will make the advantages and features of the utility model easier to understand by those skilled in the art, and thus will clearly and clearly define the scope of the utility model.

Referring to fig. 1, 2 and 3, a magnetic core casing machine includes a worktable 115, a first vibration disk 101 is fixedly connected to any side of the upper surface of the worktable 115, a second vibration disk 107 is fixedly connected to one side of the upper surface of the worktable 115, a fixed support frame 116 is fixedly connected between the first vibration disk 101 and the second vibration disk 107, the fixed support frame 116 is fixedly connected to a magnetic core assembling device, discharge ports of the first vibration disk 101 and the second vibration disk 107 are aligned to the fixed support frame 116, a fourth cylinder 112 is fixedly connected to the middle of the upper surface of the fixed support frame 116, and an assembling ring 114 is fixedly connected to the telescopic end of the fourth cylinder 112.

The upper surface of the fixed support frame 116 is fixedly connected with a second cylinder 109 at a position close to the second vibration disc 107, the telescopic end of the second cylinder 109 is fixedly connected with a third cylinder 110, and the telescopic end of the third cylinder 110 is fixedly connected with a second working clamping arm 111.

The worktable 115 and the fixed supporting frame 116 are made of manganese steel, the discharge hole of the first vibrating disk 101 is fixedly connected with a positioning ring 102, and the discharge hole of the second vibrating disk 107 is fixedly connected with a placing groove 108.

Magnetic core assembly quality includes first cylinder 103, and first cylinder 103 is close to first vibration dish 101 one side fixed connection with fixed bolster 116, and the flexible end of first cylinder 103 passes through the first revolving cylinder 104 of backup pad fixedly connected with, and the drive end position of first revolving cylinder 104 rotates and is connected with second revolving cylinder 105, and second revolving cylinder 105 drive end position rotates and is connected with first work arm lock 106, and the work end position fixedly connected with of first work arm lock 106 and second work arm lock 111 gets ring 113.

When the automatic material loading device is used, plastic shells are placed into the first vibration disc 101 in batches, magnetic cores are placed into the second vibration disc 107 in batches, the plastic shells are automatically arrayed and discharged from the first vibration disc 101 and are conveyed to the positioning ring 102 for positioning, the first air cylinder 103 drives the first rotary air cylinder 104 to ascend and descend, the first rotary air cylinder 104 drives the second rotary air cylinder 105 to rotate, and the second rotary air cylinder 105 drives the first working clamping arm 106 to turn over, so that the first working clamping arm 106 has four working positions, namely a left front side, a left back side, a right front side and a right back side, the first working clamping arm 106 takes one plastic shell at the positioning ring 102 from the left front side position and rotates to the right front side position, and the plastic shells are placed into the assembly ring 114; the magnetic cores are automatically arranged and discharged from the second vibrating disk 107 and are transmitted to the placing groove 108, the second air cylinder 109 drives the third air cylinder 110 to do horizontal linear motion, the third air cylinder 110 drives the second working clamping arm 111 to do vertical linear motion, and the second working clamping arm 111 clamps the magnetic cores at the placing groove 108 and puts the magnetic cores into the assembling ring 114 to press the magnetic cores into the plastic shell; the first working clamping arm 106 takes another plastic shell from the front left side to the positioning ring 102, turns over to the reverse right side, puts the second plastic shell into the assembly ring 114, covers the magnetic core pressed into the first plastic shell, presses down again by the second working clamping arm 111, presses the upper and lower plastic shells and the magnetic core together, and after the assembly, the fourth cylinder 112 drives the assembly ring 114 to extend out, and simultaneously drives the clamping ring 113 to switch to the assembly position for continuous assembly, and the above actions are circulated.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (6)

1. A magnetic core shell loading machine comprises a workbench (115), and is characterized in that: workstation (115) upper surface arbitrary one side position fixedly connected with first vibration dish (101), first vibration dish (101) one side position fixedly connected with second vibration dish (107) is kept away from to workstation (115) upper surface, workstation (115) upper surface is located fixedly connected with fix support frame (116) between first vibration dish (101) and second vibration dish (107), fix support frame (116) position fixedly connected with magnetic core assembly quality, fix support frame (116) are aimed at to the discharge gate of first vibration dish (101) and second vibration dish (107).

2. A magnetic core casing machine according to claim 1, characterized in that: magnetic core assembly quality includes first cylinder (103), first cylinder (103) are close to first vibration dish (101) one side fixed connection with fixed bolster (116), the flexible end of first cylinder (103) passes through the first revolving cylinder (104) of backup pad fixedly connected with, the drive end position of first revolving cylinder (104) rotates and is connected with second revolving cylinder (105), second revolving cylinder (105) drive end position rotates and is connected with first work arm lock (106).

3. A magnetic core casing machine according to claim 1, characterized in that: the middle position of the upper surface of the fixed support frame (116) is fixedly connected with a fourth cylinder (112), and the telescopic end position of the fourth cylinder (112) is fixedly connected with an assembling ring (114).

4. A magnetic core casing machine according to claim 1, characterized in that: the upper surface of the fixed support frame (116) is close to a second vibration disc (107) and is fixedly connected with a second cylinder (109), the telescopic end of the second cylinder (109) is fixedly connected with a third cylinder (110), and the telescopic end of the third cylinder (110) is fixedly connected with a second working clamping arm (111).

5. A magnetic core casing machine according to claim 2, characterized in that: and the working end positions of the first working clamping arm (106) and the second working clamping arm (111) are fixedly connected with a clamping ring (113).

6. A magnetic core casing machine according to claim 1, characterized in that: workstation (115) and fixed bolster (116) are the manganese steel material, first vibration dish (101) discharge gate position fixedly connected with holding ring (102), second vibration dish (107) discharge gate position fixedly connected with standing groove (108).

Images