CN211699998U - Following mechanism for winding coil of induction cooker - Google Patents

Abstract

The utility model provides a mechanism along with commentaries on classics of electromagnetism stove coil wire winding, it includes the board, the frame, the base station, the multistage slide rail, a plurality of slider to and drive arrangement. The frame is circular ring. The base station is fixedly connected with the sliding block. The multiple sections of slide rails form a circle, the inner diameter of the slide rails is equal to that of the rack, and the slide rails are located on the edge of the base station. The driving device comprises a main shaft, a bearing cylinder and a bearing table. The bearing cylinder moves along with the main shaft, and the base station is arranged on the bearing cylinder and moves together. This winding mechanism along with commentaries on classics of electromagnetism stove winding is when the base station atress is uneven, because the position and the effect of frame for the levelness of this base station can not warp, thereby can guarantee the precision of the wire winding module that sets up on the base station. Meanwhile, the driving device is not directly influenced by external force any more, so that the output precision of the driving device is not influenced by the pressure of the base station.

Description

Following mechanism for winding coil of induction cooker

Technical Field

The utility model relates to the technical field of mechanical equipment, in particular to wire-wound following mechanism of electromagnetism stove coil.

Background

At present, in the field of production and manufacturing of coil panels of induction cookers in China, the production and manufacturing of concave induction cookers are mostly carried out by manual winding, the consistency of electrical parameters of the coil panels is poor, the whole induction cookers are difficult to debug, and the whole performance of the induction cookers is further influenced. Then, with the great increase of the labor cost, the mechanical automation is a necessary way for enterprises to wind the induction cooker coil.

Because the winding of the induction cooker coil includes a plurality of processes, such as winding and shaping, dispensing and applying mica sheets, cleaning, blanking, and the like, in order to realize automation, a turntable-type device is often used to complete the above processes. However, in the above-mentioned processes, the stress applied to each process is not uniform, and particularly, a large pressure is often required in the last mica sheet process, which causes the stress applied to the whole equipment to be non-uniform, thereby causing the accuracy of mechanisms such as a winding mold on the equipment to be reduced and affecting the winding accuracy of the whole induction cooker coil.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a help the wire-wound mechanism of following of electromagnetism stove coil of improve equipment's bulk strength to satisfy above-mentioned demand.

The utility model provides a wire-wound mechanism that rotates along with of electromagnetism stove coil, its includes a board, one sets up frame on the board, one sets up base station in the frame, the multistage setting is in slide rail in the frame, a plurality of settings are in slider on base station and the slide rail, and a drive the rotatory drive arrangement of base station. The frame is circular ring. The base station is fixedly connected with the sliding block. The multiple sections of slide rails form a circle, the inner diameter of the slide rails is equal to that of the rack, and the slide rails are located on the edge of the base station. The driving device comprises a main shaft, a bearing cylinder arranged on the main shaft and a bearing platform arranged on the machine platform. The bearing cylinder moves along with the main shaft, and the base station is arranged on the bearing cylinder and moves together.

Further, the outer diameter of the frame is equal to the outer diameter of the base.

Further, the main shaft is located on a central shaft of the frame.

Further, the number of the sliding blocks is more than 8.

Further, the slide rail includes a body and two flanges disposed in a radial direction of the body in a cross section along the slide rail.

Further, the connecting part of the flange and the body is arc-shaped.

Further, the slider has a groove that mates with the flange.

Furthermore, the driving device also comprises a supporting frame arranged on the other side of the bearing platform relative to the base station, and the spindle is arranged between the bearing cylinder and the supporting frame.

Further, the bearing cylinder is connected with the bearing platform in a sliding way through a bearing

Compared with the prior art, the utility model provides a wire-wound mechanism of following with of electromagnetism stove winding sets up the frame through setting up on the board, and the base station pass through slider and slide rail with the frame is connected, and the slide rail is located the edge of base station. When the winding module is arranged on the base station, even if the base station is stressed unevenly, the levelness of the base station cannot be deformed due to the position and the action of the rack, so that the precision of the winding module arranged on the base station can be ensured. Meanwhile, the driving device is not directly influenced by external force any more, so that the output precision of the driving device is not influenced by the pressure of the base station.

Drawings

Fig. 1 is an exploded schematic view of a winding following mechanism of an induction cooker coil provided by the present invention.

Fig. 2 is an assembly structure diagram of a follow-up mechanism of the coil winding of the induction cooker of fig. 1.

Fig. 3 is a schematic cross-sectional structure view of a slide rail of a follow-up mechanism for coil winding of the induction cooker of fig. 1.

Detailed Description

Specific examples of the present invention will be described in further detail below. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.

As shown in fig. 1 to fig. 3, it is a schematic structural diagram of a rotation following mechanism for winding a coil of an induction cooker according to the present invention. The following mechanism for winding the coil of the induction cooker comprises a machine table 10, a machine frame 20 arranged on the machine table 10, a base table 30 arranged on the machine frame 20, a plurality of sections of slide rails 40 arranged on the machine frame 20, a plurality of slide blocks 50 arranged on the base table 30 and the slide rails 40, and a driving device 60 for driving the base table 30 to rotate. It is contemplated that the following mechanism for winding the coil of the induction cooker may further include other functional modules, such as assembling components, mounting components, electrical connecting components, etc., which are well known to those skilled in the art and will not be described herein.

The machine 10 is a conventional machine for carrying various functional modules, such as an electrical module, a feeding module, a dispensing module, and the like. Therefore, its size, shape, and strength should meet practical requirements. In the drawings, only a square plate is shown to illustrate the machine 10.

The frame 20 may be a circular ring and is fixedly disposed on the machine 10. The frame 20 may be formed by assembling a plurality of arcuate segments. The outer diameter of the frame 20 should be set according to the diameter of the base 30, and preferably, the outer diameter of the frame 20 is equivalent to the diameter of the base 30.

The base 30 is used for mounting a plurality of winding dies and accessories such as a driving mechanism and the like related to the winding dies. The base 30 is circular so that a plurality of steps can be performed in order by rotating the base 30. In this embodiment, the base 30 can be provided with 4 winding modules, each winding module has two winding dies to improve the production efficiency.

The slide rail 40 is fixed on the frame 20 and is formed by combining a plurality of sections of arc-shaped guide rails, that is, the plurality of sections of slide rails form a circle, and the inner diameter of the slide rail 40 is equal to the inner diameter of the frame 20 and is located at the edge of the base station 30, so that the force applied to the base station 30 can be completely transmitted to the frame 20. In the present embodiment, the slide rail 40 is composed of six arc-shaped guide rails. Meanwhile, the slide rail 40 and the frame 20 are disposed at the edge of the base 30, so that the base 30 will not be tilted left and right by taking the driving device 60 as a center, which results in a decrease in precision. Meanwhile, in order to ensure the stability of the base 30, the slide rail 40 includes a body 41 and two flanges 42 provided in the radial direction of the body 41 in a cross section along the slide rail 40. The junction of the flange 42 and the body 41 is arcuate and functions as described below in conjunction with the slider 50.

The slide block 50 is fixedly arranged on the base platform 30 and is arranged on the slide rail 40 in a sliding manner. In order to ensure the uniform force applied to the base 30, the number of the sliding blocks 50 should be more than 8. In this embodiment, the number of the sliders 50 is 12, that is, 3 sliders are allocated to each winding former group for supporting. The slider 50 is configured to mate with the slide track 40 such that the slider 50 has a recess 51 that mates with the flange 42. It is contemplated that the track 40 and the slider 50 are standard components, as is well known in the art, and that the groove 51 and the flange 42 may be preceded by balls to reduce friction. Because the joint of the flange 42 and the body 41 is arc-shaped, it not only has a supporting function for the slider 50, but also is beneficial to reducing the influence of the slider swaying along the diameter direction of the base platform 30, thereby avoiding swaying left and right when the base platform 30 is stressed left and right.

The driving device 60 includes a main shaft 61, a bearing cylinder 62 disposed on the main shaft 61, a bearing platform 63 disposed on the machine platform 10, and a supporting frame 64 disposed on the other side of the bearing platform 63 opposite to the base platform 30. It is contemplated that the drive 60 may also include functional structures such as motors, gears, belts, etc. as would be known to one skilled in the art. The spindle 61 is disposed between the bearing cylinder 62 and the supporting frame 64, and one end thereof is fixedly connected to the base 30 to drive the base 30 to rotate when the spindle 61 rotates. The main shaft 61 is located on a central axis of the frame 20. The bearing cylinder 62 is fixed to the spindle 61 and is used to fix the base 30 to each other. The bearing table 63 is disposed on the machine table 10 and used for bearing the main shaft 61, the bearing cylinder 62, and functional elements such as a motor. The support frame 64 is disposed on the bearing platform 63 and is used for accommodating components such as gears and transmission belts, so as to prevent personnel from being injured during maintenance.

Compared with the prior art, the utility model provides a wire-wound mechanism of following with of electromagnetism stove winding sets up frame 20 through setting up on board 10, and base station 30 through slider 50 and slide rail 40 with frame 20 is connected, and slide rail 40 is located the edge of base station 30. When the winding module is disposed on the base 30, even if the base 30 is stressed unevenly, the levelness of the base 30 will not be deformed due to the position and function of the frame 20, so as to ensure the accuracy of the winding module disposed on the base 30. Meanwhile, the driving device is not directly influenced by external force any more, so that the output precision of the driving device is not influenced by the pressure of the base station.

The above description is only for the preferred embodiment of the present invention and should not be construed as limiting the scope of the present invention, and any modification, equivalent replacement or improvement within the spirit of the present invention is encompassed by the claims of the present invention.

Claims (9)

1. The utility model provides a mechanism is rotated along with of electromagnetism stove coil winding which characterized in that: the winding following rotation mechanism of the induction cooker coil comprises a machine table, a machine frame arranged on the machine table, a base station arranged on the machine frame, a plurality of sections of slide rails arranged on the machine frame, a plurality of slide blocks arranged on the base station and the slide rails, and a driving device for driving the base station to rotate, wherein the machine frame is in a circular ring shape, the base station is fixedly connected with the slide blocks, the slide rails form a circle, the inner diameter of the slide rail is equal to the inner diameter of the machine frame and is positioned at the edge of the base station, the driving device comprises a main shaft, a bearing barrel arranged on the main shaft, and a bearing table arranged on the machine table, the bearing barrel moves along with the main shaft, and the base station is arranged on the bearing barrel and moves together.

2. The follow-up mechanism for coil winding of induction cooker as claimed in claim 1, wherein: the outer diameter of the frame is equal to the outer diameter of the base station.

3. The follow-up mechanism for coil winding of induction cooker as claimed in claim 1, wherein: the main shaft is positioned on a central shaft of the frame.

4. The follow-up mechanism for coil winding of induction cooker as claimed in claim 1, wherein: the number of the sliding blocks is more than 8.

5. The follow-up mechanism for coil winding of induction cooker as claimed in claim 1, wherein: the slide rail comprises a body and two flanges arranged in the radial direction of the body in a section along the slide rail.

6. The follow-up mechanism for coil winding of induction cooker according to claim 5, characterized in that: the connecting part of the flange and the body is arc-shaped.

7. The follow-up mechanism for coil winding of induction cooker according to claim 6, characterized in that: the slider has a groove that mates with the flange.

8. The follow-up mechanism for coil winding of induction cooker as claimed in claim 1, wherein: the driving device also comprises a supporting frame arranged on the other side of the bearing platform relative to the base station, and the spindle is arranged between the bearing cylinder and the supporting frame.

9. The follow-up mechanism for coil winding of induction cooker according to claim 8, characterized in that: the bearing cylinder is connected with the bearing table in a sliding mode through a bearing.

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