CN111017509A

CN111017509A - Automatic inductance correction and conveying device

Info

Publication number: CN111017509A
Application number: CN201911352852.6A
Authority: CN
Inventors: 周兰凤; 江华奇
Original assignee: Intelligent Components Technology Zhuhai Ltd (china)
Current assignee: Intelligent Components Technology Zhuhai Ltd (china)
Priority date: 2019-12-25
Filing date: 2019-12-25
Publication date: 2020-04-17

Abstract

The invention discloses an automatic inductance correction conveying device which comprises a control system, a transmission rail, a motor and a correction module, wherein the motor is positioned on the transmission rail and used for driving the transmission rail, the correction module is positioned at the front part of the transmission rail, an optical fiber sensor is arranged on the correction module, and the motor and the optical fiber sensor are both electrically connected with the control system. The automatic inductance correction and conveying device is stable in performance, can automatically correct the direction of the inductance, and improves the automatic inductance conveying and machining efficiency.

Description

Automatic inductance correction and conveying device

Technical Field

The invention relates to the technical field of electromagnetic elements, in particular to an automatic inductance correction conveying device.

Background

An inductor is an electronic component that converts electrical energy into magnetic energy for storage. Inductors are typically comprised of a bobbin, coil winding, shield, potting material, core or core, and the like. The production process of the inductor mainly comprises the steps of feeding, framework winding, PIN foot adding, PIN foot tinning, performance testing and the like. At present, in the automatic production process of an inductor, a processing device in a complete inductor production line generally comprises a feeding device, a winding machine, a tin dipping machine, a detection device and the like. After the inductor is processed in the processing device, the inductor is usually placed on a conveyor belt by a robot arm, and is transported to the next processing device by the conveyor belt. The prior inductance conveying device has the following problems: after the inductor is placed on the conveyor belt from the processing device by the manipulator, the direction of the inductor is inconsistent, the deflection phenomenon is easy to occur, and the material blocking in the subsequent conveying process is easy to cause; meanwhile, the orientation of the inductor has a great influence on subsequent processing, and if the inductor cannot be guaranteed to be kept in the correct direction in the conveying process, the inductor cannot be accurately processed by the next processing device, so that the production efficiency and the quality of a product are influenced.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides an automatic inductance correction conveying device which is stable in performance, can automatically correct the direction of an inductance and improves the automatic inductance conveying and processing efficiency.

The technical scheme adopted by the invention is as follows:

the automatic inductance correction and conveying device comprises a control system, a transmission track, a motor and a correction module, wherein the motor is located on the transmission track and used for driving the transmission track, the correction module is located at the front part of the transmission track, an optical fiber inductor is arranged on the correction module, and the motor and the optical fiber sensor are both electrically connected with the control system.

When the optical fiber inductor on the correction module senses the inductor placed on the transmission track, the correction device can start to correct the direction of the inductor, and then the motor is started to transmit.

Furthermore, the correction module comprises a fixed baffle arranged on one side of the transmission track, a sliding baffle arranged on the other side of the transmission track, and a sliding assembly arranged below the transmission track, wherein the sliding assembly is fixedly connected with the sliding baffle. The sliding assembly can drive the sliding baffle to slide towards the outer side of the conveying track under the action of power.

Further, the sliding assembly comprises an air cylinder, a connecting rod connected with the air cylinder and a sliding guide rail connected with the connecting rod, the air cylinder comprises a cylinder body and a piston rod, the connecting rod is connected with the piston rod, and the sliding guide rail is connected with the sliding baffle.

Furthermore, the rear end of the transmission track is provided with an adjusting module, the adjusting module comprises an adjusting baffle plate positioned at the upper end of the transmission track, a fixing plate positioned at the side end of the transmission track and a connecting screw rod, and the fixing plate is connected to the side end of the transmission track through the connecting screw rod. The baffle can be adjusted to ensure that the corrected inductor can continuously keep the correct direction for transmission.

Further, be equipped with the spring between the side of fixed plate and transmission track, can be through precession and the connecting screw rod of back-out to adjust the position of adjustment baffle on transmission track, thereby change the distance between adjustment baffle and the fixed stop, with the inductance of adaptation different width sizes.

Furthermore, an optical fiber sensor, an air pipe and an electromagnetic valve arranged on the air pipe are arranged on the adjusting baffle. When the inductor with the declined direction enters the adjusting module and is blocked, the optical fiber sensor can monitor the blocking phenomenon and control the electromagnetic valve to open and blow air through the control system, so that the inductor with the declined direction is blown back to the area of the correcting module and is corrected again.

Compared with the prior art, the invention has the following beneficial effects:

the inductance transmission track is provided with the correction module and the adjustment module, so that the direction-inclined inductance is automatically corrected, the inductance is conveniently conveyed and further precisely processed, and the quality and the production efficiency of inductance products are greatly improved.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic view of a connecting structure of an adjusting baffle and a conveying track in the invention.

The labels in the figure are: 1-a transfer track; 2, a motor; 3-a fiber optic sensor; 41-fixed baffle; 42-a sliding baffle; 431-connecting rod; 432-a sliding guide; 433-cylinder body; 434-a piston rod; 51-adjusting the baffle; 52-a fixed plate; 53-connecting screw; 54-a spring; 55-trachea; 56-electromagnetic valve.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1 to 2, the automatic inductance correction and conveying device includes a control system, a transmission rail, a motor located on the transmission rail and used for driving the transmission rail, and a correction module located at the front of the transmission rail, wherein an optical fiber sensor is arranged on the correction module, and the motor and the optical fiber sensor are both electrically connected to the control system.

The correcting module comprises a fixed baffle arranged on one side of the conveying track, a sliding baffle arranged on the other side of the conveying track and a sliding assembly arranged below the conveying track, wherein the sliding assembly is fixedly connected with the sliding baffle. The sliding assembly can drive the sliding baffle to slide towards the outer side of the conveying track under the action of power.

The sliding assembly comprises a cylinder, a connecting rod connected with the cylinder and a sliding guide rail connected with the connecting rod, the cylinder comprises a cylinder body and a piston rod, the connecting rod is connected with the piston rod, and the sliding guide rail is connected with the sliding baffle.

The rear end of the transmission track is provided with an adjusting module, the adjusting module comprises an adjusting baffle positioned at the upper end of the transmission track, a fixing plate positioned at the side end of the transmission track and a connecting screw rod, and the fixing plate is connected to the side end of the transmission track through the connecting screw rod. The baffle can be adjusted to ensure that the corrected inductor can continuously keep the correct direction for transmission.

The spring is arranged between the side ends of the fixed plate and the transmission track, and the connecting screw rod can be screwed in and out, so that the position of the adjusting baffle plate on the transmission track can be adjusted, the distance between the adjusting baffle plate and the fixed baffle plate can be changed, and the inductors with different width sizes can be adapted. And the adjusting baffle is provided with an optical fiber sensor, an air pipe and an electromagnetic valve arranged on the air pipe.

When the optical fiber inductor on the correction module senses the inductor placed on the transmission track, the correction device can start to correct the direction of the inductor, and then the motor is started to transmit. If the inductor with the declined direction enters the adjusting module and the material is blocked, the optical fiber sensor on the adjusting module can monitor the material blocking phenomenon, and the control system controls the electromagnetic valve to open and blow air, so that the inductor with the declined direction is blown back to the area of the correcting module and is corrected again.

The present invention has been described in detail with reference to the specific embodiments. However, the present invention is not limited to the above description. Variations that do not depart from the gist of the invention are intended to be within the scope of the invention.

Claims

1. The automatic feeding device for the inductance framework comprises a base, a material tray, a vibrating motor, a spiral feeding rail and a discharging rail, wherein the vibrating motor is installed below the material tray, the spiral feeding rail is arranged in the middle of the material tray, the discharging rail comprises two parallel rail belts, a material clamping gap is arranged between the two rail belts, and the width of the material clamping gap is larger than the width of the upper part of the inductance and smaller than the width of the lower part of the inductance; the method is characterized in that: the device comprises a discharge rail, and is characterized in that a first adjusting part and a second adjusting part are sequentially arranged on the discharge rail, the first screening part comprises an arc rail belt and an air blowing pipe which are arranged in parallel from top to bottom, the second adjusting part comprises a baffle connected to the outer side end of the discharge rail, an air blowing pipe located at the front end of the baffle and a rail notch located in the baffle, the length of the rail notch is greater than the width of an inductor, and a clamping groove is formed in the inner side of the baffle.

2. The inductance framework automatic feeding device according to claim 1, characterized in that: and an adjusting groove is arranged on the track at the rear end of the first adjusting part.

3. The inductance framework automatic feeding device according to claim 2, characterized in that: the rear end of the adjusting groove is provided with an air blowing pipe.

4. The inductance framework automatic feeding device according to claim 3, characterized in that: and the tail end of the discharging track is provided with an optical fiber sensor.