CN216661661U - Inductance housing feed mechanism - Google Patents

Abstract

The utility model relates to the technical field of I-shaped inductor production, and discloses an inductor shell feeding mechanism which comprises a base, a rotating disc, a vibrating feeding disc, a pushing assembly and elastic clamping jaws, wherein the rotating disc is rotatably arranged on the base; the vibrating feeding plate is provided with a feeding channel, and the feeding channel extends to the edge of the rotating plate; the pushing assembly is arranged on the base; the elastic clamping jaw is arranged at the edge of the rotating disc. When feeding is needed, the rotating disc drives the elastic clamping jaw to rotate to the feeding opening; pushing the elastic clamping jaws towards the feeding hole by the pushing assembly so that the elastic clamping jaws are opened, and vibrating the feeding disc to convey the inductor shell into the elastic clamping jaws in a vibrating manner; then, the pushing assembly is separated from the elastic clamping jaw, and the elastic clamping jaw can automatically clamp the inductor shell; the rotating disc continues to rotate, the inductor shell can be conveyed to the press-fitting station, continuous feeding of the inductor shell is achieved, mass production and production automation of the inductor shell are facilitated, and support can be provided for mass production and production automation of the I-shaped inductor.

Description

Inductance housing feed mechanism

Technical Field

The utility model relates to the technical field of inductor production, in particular to an inductor shell feeding mechanism.

Background

The i-shaped inductor is a plug-in inductor, and has a structure shown in fig. 1, and includes an inductor frame and an inductor housing sleeved outside the inductor frame. When an I-shaped inductor is processed and produced, an inductor framework and an inductor shell need to be processed respectively, and then the inductor framework is pressed into the inductor shell. At present, some small manufacturers press the inductor framework into the inductor shell by adopting a manual press-fitting mode, or press-fitting by adopting a single machine. However, the press fitting efficiency of the two press fitting modes is low, and the press fitting modes are not beneficial to mass production of large-scale manufacturers.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide the inductor shell feeding mechanism which can realize continuous feeding of the inductor shell and provide support for mass production and production automation of the I-shaped inductors.

In order to solve the problems, the technical scheme adopted by the utility model is as follows: an inductance enclosure feed mechanism, comprising: a base; the rotating disc is rotatably arranged on the base; the vibrating feeding plate is provided with a feeding channel, and the feeding channel extends to the edge of the rotating plate; a pushing assembly mounted on the base; the elastic clamping jaw is arranged at the edge position of the rotating disc; elastic clamping jaw can follow the rolling disc rotates, works as elastic clamping jaw rotates the alignment during material loading passageway's material loading mouth, it can move towards to bulldoze the material loading mouth elastic clamping jaw, so that elastic clamping jaw opens, material loading disc can be followed with the inductance housing in the vibration material loading mouth is carried extremely in the elastic clamping jaw.

Compared with the prior art, the utility model has the beneficial effects that: when feeding is needed, the rotating disc drives the elastic clamping jaw to rotate to the feeding port, and the head of the elastic clamping jaw is aligned to the feeding port; pushing the elastic clamping jaw towards the feeding hole by the pushing assembly to open the elastic clamping jaw, and conveying the inductor shell into the elastic clamping jaw by vibrating the feeding disc at the moment; then, the pushing assembly is separated from the elastic clamping jaw, and the elastic clamping jaw can automatically clamp the inductor shell; the rotating disc continues to rotate, and the inductor shell can be conveyed to a press fitting station. Consequently, this feed mechanism passes through the rolling disc, vibrates the charging tray, bulldozes the cooperation between subassembly and the elastic clamping jaw, can realize the lasting material loading of inductance housing, is favorable to the mass production and the production automation of inductance housing, can provide support for the mass production and the production automation of I-shaped inductance.

Foretell inductance housing feed mechanism still includes backstop subassembly, backstop subassembly includes: the mounting frame is arranged on one side of the feeding channel; the first driving piece is mounted on the mounting frame; the stop block is connected to the output end of the first driving piece; the former inductance housing is followed the material loading mouth gets into after in the elastic clamping jaw, first driving piece can drive the backstop piece stretches into the material loading mouth to backstop next inductance housing.

In the above feeding mechanism for the inductor housing, the moving direction of the stop block is perpendicular to the extending direction of the feeding channel.

Foretell inductance housing feed mechanism, the backstop piece has plane portion and arc pothook, plane portion with arc pothook transitional coupling, plane portion is on a parallel with the lateral wall of material loading passageway, the arc pothook is than plane portion is closer to in the material loading mouth, the arc pothook is used for the backstop inductance housing.

The elastic clamping jaw comprises a first clamping block and a second clamping block, the first clamping block and the second clamping block are arranged in a crossed mode and are connected in a rotating mode, and the tail portion of the first clamping block is connected with the tail portion of the second clamping block through an elastic connecting piece.

In the inductance housing feeding mechanism, the head of the first clamping block and the head of the second clamping block are respectively provided with the first arc-shaped clamping part and the second arc-shaped clamping part, and the first arc-shaped clamping part and the second arc-shaped clamping part can be matched with each other to clamp the inductance housing.

The elastic clamping jaw further comprises a positioning block, the positioning block is mounted at the edge position of the rotating disc, a positioning groove used for positioning the inductor shell is formed in the head of the positioning block, the positioning groove is located between the first arc-shaped clamping portion and the second arc-shaped clamping portion, and the first clamping block and the second clamping block are rotatably connected with the positioning block.

In the above feeding mechanism for the inductor housing, the outer edge of the feeding channel and the outer edge of the head of the positioning block are both arc surfaces concentric with the rotating disc.

Above-mentioned inductance housing feed mechanism, bulldoze the subassembly and include: the second driving piece is arranged on the base; the pushing block is connected to the output end of the second driving piece; the second driving piece can drive the pushing block to move towards the tail part of the elastic clamping jaw, so that the pushing block pushes the elastic clamping jaw and the elastic clamping jaw is opened.

Foretell inductance housing feed mechanism, the subassembly that bulldozes still includes the pushing wheel, the pushing wheel connect in the lower extreme of ejector pad, the ejector pad orientation when the afterbody of elasticity clamping jaw removes, the pushing wheel can block in the afterbody of elasticity clamping jaw.

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Drawings

Fig. 1 is a schematic structural diagram of an i-inductor;

FIG. 2 is a schematic view of a part of the structure of a feeding mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a stop assembly according to an embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 2 at A;

FIG. 5 is a schematic diagram of a resilient jaw according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a pushing assembly according to an embodiment of the utility model.

The reference numbers illustrate:

100I-shaped inductors, 110 inductor shells and 120 inductor frameworks;

200 a base;

300 a turntable;

400 of a feeding channel;

500 pushing component, 510 second driving component, 520 pushing block and 530 pushing wheel;

600 elastic clamping jaws, 610 first clamping blocks, 611 first arc-shaped clamping parts, 620 second clamping blocks, 621 second arc-shaped clamping parts, 630 positioning blocks, 631 positioning grooves and 640 elastic connecting pieces;

700 backstop subassembly, 710 mounting bracket, 720 first drive spare, 730 backstop piece, 731 plane portion, 732 arc pothook.

Detailed Description

Describing an embodiment of the present invention in detail, referring to fig. 2 to 6, an embodiment of the present invention provides an inductor housing feeding mechanism, including a base 200, a rotating disc, a vibrating feeding tray, a pushing assembly 500, and elastic clamping jaws 600, wherein the rotating disc is rotatably mounted on the base 200; the vibrating feeding plate is provided with a feeding channel 400, and the feeding channel 400 extends to the edge of the rotating plate; the pushing assembly 500 is mounted to the base 200; the elastic clamping jaws 600 are arranged at the edge position of the rotating disc; the elastic clamping jaws 600 can rotate along with the rotating disc, when the elastic clamping jaws 600 rotate to align with the feeding opening of the feeding channel 400, the pushing assembly 500 can push the elastic clamping jaws 600 towards the feeding opening, so that the elastic clamping jaws 600 are opened, and the inductor shell 110 can be conveyed into the elastic clamping jaws 600 from the feeding opening by vibrating the feeding tray.

When feeding is needed, the rotating disc drives the elastic clamping jaw 600 to rotate to the feeding port, and the head of the elastic clamping jaw 600 is aligned to the feeding port; the pushing assembly 500 pushes the elastic clamping jaws 600 towards the feeding hole, so that the elastic clamping jaws 600 are opened, and at the moment, the inductor shell 110 can be conveyed into the elastic clamping jaws 600 in a vibrating manner by vibrating the feeding plate; thereafter, the pushing assembly 500 is disengaged from the elastic clamping jaw 600, and the elastic clamping jaw 600 will automatically clamp the inductor housing 110; the rotating disc continues to rotate and can convey the inductor housing 110 to the press-fitting station. Therefore, this feed mechanism passes through the rolling disc, vibrates the material loading dish, bulldozes the cooperation between subassembly 500 and the elastic clamping jaw 600, can realize the lasting material loading of inductance housing 110, is favorable to the mass production and the production automation of inductance housing 110, can provide support for the mass production and the production automation of I-shaped inductance 100.

In fig. 2, in order to clearly see the structure of the feeding mechanism according to the embodiment of the present invention, the structure of the vibrating feeding tray is not shown in fig. 2, and the vibrating feeding tray is a structure used in normal feeding. In the embodiment of the present invention, the plurality of elastic clamping jaws 600 are provided, and the plurality of elastic clamping jaws 600 are distributed along the circumferential direction of the rotating disk 300. The feeding channel 400 is provided with two sets, and can feed two sets of inductor housings 110 simultaneously.

Further, referring to fig. 3, the feeding mechanism further includes a stopping assembly 700, the stopping assembly 700 includes a mounting frame 710, a first driving member 720 and a stopping block 730, the mounting frame 710 is disposed at one side of the feeding channel 400; the first driving member 720 is mounted on the mounting frame 710; the stop block 730 is connected to the output end of the first driving member 720; after the previous inductor housing 110 enters the elastic clamping jaw 600 from the feeding opening, the first driving member 720 can drive the stopping block 730 to extend into the feeding opening to stop the next inductor housing 110, so that the subsequent inductor housing 110 can not fall out of the feeding opening after the rotating disk drives the elastic clamping jaw 600 to move away. When the next elastic clamping jaw 600 rotates to the feeding port, the first driving member 720 drives the stopping block 730 to retreat, so that the inductor housing 110 can enter the elastic clamping jaw 600 from the feeding port, and then the first driving member 720 drives the stopping block 730 to extend into the feeding port again, so as to circulate.

Specifically, the moving direction of the stopper 730 is perpendicular to the extending direction of the feeding channel 400, so that the installation of the stopper assembly 700 can be facilitated, and the occurrence of motion interference can be avoided. Specifically, with continued reference to fig. 3, the stopping block 730 has a planar portion 731 and an arc-shaped hook 732, the planar portion 731 is in transition connection with the arc-shaped hook 732, the planar portion 731 is parallel to the sidewall of the feeding channel 400, the arc-shaped hook 732 is closer to the feeding port than the planar portion 731, and the arc-shaped hook 732 is used for stopping the inductor housing 110. Referring to fig. 4, when the inductor housing 110 needs to be stopped, the stop block 730 enters the feeding opening, the plane portion 731 just abuts against the outer wall of the inductor housing 110, and the arc-shaped hook 732 just hooks the inductor housing 110. The arc-shaped hook 732 is designed to be arc-shaped, so that the arc-shaped hook 732 can smoothly hook the inductor housing 110 or disengage from the inductor housing 110.

Further, referring to fig. 5, the elastic clamping jaw 600 includes a first clamping block 610 and a second clamping block 620, the first clamping block 610 and the second clamping block 620 are arranged crosswise and rotatably connected with each other, and the tail portion of the first clamping block 610 and the tail portion of the second clamping block 620 are connected with each other by an elastic connection member 640. When the tail of the resilient jaw 600 is pushed, the head of the resilient jaw 600 opens allowing the outside of the inductor to enter the resilient jaw 600. When the pushing assembly 500 cancels the pushing force on the elastic clamping jaw 600, the elastic clamping jaw 600 is restored to the original shape and can maintain the clamped state under the action of the elastic connecting piece 640, so as to clamp the inductance housing 110.

Still further, the head of the first clamping block 610 and the head of the second clamping block 620 are respectively provided with a first arc-shaped clamping portion 611 and a second arc-shaped clamping portion 621, and the first arc-shaped clamping portion 611 and the second arc-shaped clamping portion 621 can be matched with each other to clamp the inductor housing 110, so that the inductor housing 110 can be clamped, and the inductor housing 110 cannot be damaged.

Further, with reference to fig. 5, the elastic clamping jaw 600 further includes a positioning block 630, the positioning block 630 is installed at an edge position of the rotating disc, a positioning groove 631 for positioning the inductor housing 110 is formed at a head portion of the positioning block 630, the positioning groove 631 is located between the first arc-shaped clamping portion 611 and the second arc-shaped clamping portion 621, and the first clamping block 610 and the second clamping block 620 are both rotatably connected to the positioning block 630. Specifically, as shown in fig. 5, the head of the positioning groove 631 has an opening, so that the inductor housing 110 can smoothly enter the positioning groove 631 from the opening, and then the inductor housing 110 is clamped by the first clamping block 610 and the second clamping block 620, which can perform a good fixing and positioning function on the inductor housing 110. Specifically, the outer edge of the feeding channel 400 and the outer edge of the head of the positioning block 630 are both in the shape of an arc concentric with the rotating disc. Not only can ensure that the inductor housing 110 smoothly enters the elastic clamping jaw 600 from the feeding port, but also can avoid the motion interference between the feeding channel 400 and the elastic clamping jaw 600 when the turntable 300 rotates.

Specifically, referring to fig. 6, the pushing assembly 500 includes a second driving member 510 and a pushing block 520, the second driving member 510 being mounted to the base 200; the pushing block 520 is connected to the output end of the second driving member 510; the second driving member 510 can drive the pushing block 520 to move towards the tail of the elastic clamping jaw 600, so that the pushing block 520 pushes the elastic clamping jaw 600 and the elastic clamping jaw 600 is opened. Specifically, the pushing assembly 500 further includes a pushing wheel 530, the pushing wheel 530 is connected to a lower end of the pushing block 520, and when the pushing block 520 moves toward the tail portion of the elastic clamping jaw 600, the pushing wheel 530 can be snapped into the tail portion of the elastic clamping jaw 600, so as to effectively push the tail portion of the elastic clamping jaw 600, and the head portion of the elastic clamping jaw 600 is opened.

It should be noted that in the description of the present invention, if orientation descriptions such as the directions of up, down, front, back, left, right, etc. are referred to, all the orientations or positional relationships are based on the directions or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but not for indicating or implying that the referred device or element must have a specific orientation, be constructed or operated in a specific orientation, and should not be construed as limiting the present invention.

In the description of the present invention, the meaning of a plurality of means is one or more, the meaning of a plurality of means is two or more, and more than, less than, more than, etc. are understood as excluding the present number, and more than, less than, etc. are understood as including the present number. The description to first or second etc. is for the purpose of distinguishing between technical features and is not to be construed as indicating or implying a relative importance or implying a number of indicated technical features or implying a precedence relationship between indicated technical features.

In the description of the present invention, unless otherwise explicitly limited, terms such as arrangement, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention in combination with the specific contents of the technical solutions.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention is not limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are within the protection scope of the present invention.

Claims (10)

1. An inductance housing feed mechanism, characterized in that includes:

a base (200);

a rotating disk rotatably mounted to the base (200);

the vibrating feeding disc is provided with a feeding channel (400), and the feeding channel (400) extends to the edge of the rotating disc;

a pushing assembly (500) mounted on the base (200); and

the elastic clamping jaw (600) is arranged at the edge position of the rotating disc;

elasticity clamping jaw (600) can follow the rolling disc rotates, works as elasticity clamping jaw (600) rotate and aim at when the material loading mouth of material loading passageway (400), it can face to bulldoze subassembly (500) elasticity clamping jaw (600) to make elasticity clamping jaw (600) open, the material loading dish can be followed inductance shell (110) in the vibration the material loading mouth is carried extremely in elasticity clamping jaw (600).

2. The inductance housing feeding mechanism of claim 1, further comprising a stopping assembly (700), wherein the stopping assembly (700) comprises:

the mounting frame (710) is arranged on one side of the feeding channel (400);

a first drive member (720) mounted to the mounting bracket (710);

a stop block (730) connected to the output end of the first driving member (720);

after the previous inductance housing (110) enters the elastic clamping jaw (600) from the feeding port, the first driving piece (720) can drive the stop block (730) to extend into the feeding port so as to stop the next inductance housing (110).

3. The inductance housing feeding mechanism according to claim 2, wherein the moving direction of the stop block (730) is perpendicular to the extending direction of the feeding channel (400).

4. The inductance housing feeding mechanism according to claim 3, wherein the stop block (730) has a planar portion (731) and an arc-shaped hook (732), the planar portion (731) is in transition connection with the arc-shaped hook (732), the planar portion (731) is parallel to a sidewall of the feeding channel (400), the arc-shaped hook (732) is closer to the feeding opening than the planar portion (731), and the arc-shaped hook (732) is used for stopping the inductance housing (110).

5. The inductance housing feeding mechanism according to claim 1, wherein the elastic clamping jaw (600) comprises a first clamping block (610) and a second clamping block (620), the first clamping block (610) and the second clamping block (620) are arranged in a crossed manner and are rotatably connected with each other, and the tail portion of the first clamping block (610) and the tail portion of the second clamping block (620) are connected with each other through an elastic connecting piece (640).

6. The inductance housing feeding mechanism according to claim 5, wherein the head of the first clamping block (610) and the head of the second clamping block (620) are respectively provided with a first arc-shaped clamping portion (611) and a second arc-shaped clamping portion (621), and the first arc-shaped clamping portion (611) and the second arc-shaped clamping portion (621) can mutually cooperate to clamp the inductance housing (110).

7. The inductance housing feeding mechanism according to claim 6, wherein the elastic clamping jaw (600) further comprises a positioning block (630), the positioning block (630) is mounted at an edge of the rotating disc, a positioning groove (631) for positioning the inductance housing (110) is formed at a head of the positioning block (630), the positioning groove (631) is located between the first arc-shaped clamping portion (611) and the second arc-shaped clamping portion (621), and the first clamping block (610) and the second clamping block (620) are both rotatably connected to the positioning block (630).

8. The inductance housing feeding mechanism according to claim 7, wherein the outer edge of the feeding channel (400) and the outer edge of the head of the positioning block (630) are both in the shape of an arc concentric with the rotating disc.

9. The inductance housing feeding mechanism of claim 1, wherein said pushing assembly (500) comprises:

a second driving member (510) mounted to the base (200);

the push block (520) is connected to the output end of the second driving piece (510);

the second driving piece (510) can drive the pushing block (520) to move towards the tail of the elastic clamping jaw (600), so that the pushing block (520) pushes the elastic clamping jaw (600) and the elastic clamping jaw (600) is opened.

10. The inductance housing feeding mechanism of claim 9, wherein the pushing assembly (500) further comprises a pushing wheel (530), the pushing wheel (530) is connected to a lower end of the pushing block (520), and when the pushing block (520) moves towards the tail of the elastic clamping jaw (600), the pushing wheel (530) can be clamped into the tail of the elastic clamping jaw (600).

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