CN217624360U

CN217624360U - Cylindricality terminal feed mechanism

Info

Publication number: CN217624360U
Application number: CN202221233056.8U
Authority: CN
Inventors: 虞新剑
Original assignee: Dongguan Xurui Precision Technology Co ltd
Current assignee: Dongguan Xurui Precision Technology Co ltd
Priority date: 2022-05-20
Filing date: 2022-05-20
Publication date: 2022-10-21
Anticipated expiration: 2032-05-20

Abstract

The utility model discloses a cylindricality terminal feed mechanism installs in frame department, including being used for sequencing the vibration dish of carrying, being used for accepting one by one to mixed and disorderly cylindricality terminal the cylindricality terminal that the vibration dish carried and make the cylindricality terminal continue the transport cell body of carrying forward and right the cylindricality terminal that the transport cell body carried shifts the loading gear of material loading. Carry the cell body to have towards keeping away from the slope passageway of the direction downward sloping of vibration dish, the material loading gear is followed the direction that slope passageway carried the cylindricality terminal is located carry the front side next door of cell body, a plurality of edges of material loading gear have been seted up jointly and have been arranged into the tooth's socket of accepting of round equally spaced ground in the circumference of material loading gear, every it is in to accept the tooth's socket material loading gear pivoted in-process rotatory extremely with the material receiving position that the slope passageway is aligned. The utility model discloses a cylindricality terminal feed mechanism can realize the purpose of cylindricality terminal individual automatic feeding.

Description

Cylindricality terminal feed mechanism

Technical Field

The utility model relates to a packing field of cylindricality terminal especially relates to a cylindricality terminal feed mechanism that cylindricality terminal packing was used.

Background

As is well known, a probe is widely used in testing, electrical connection, and the like, and belongs to one of precision components.

In the processing process of the probe, the cylindrical terminal in the probe needs to be subjected to gold plating treatment according to the process requirement. Because the machining place of the cylindrical terminals and the gold plating place of the cylindrical terminals are in different workshops, the cylindrical terminals are convenient to transport, the cylindrical terminals are clamped in clamping grooves preset on a carrier tape, the carrier tape realizes the releasing and winding actions of the carrier tape by the cooperative matching of an unwinding wheel and a winding wheel, and the purposes of batch packaging of the cylindrical terminals and convenient transportation by using the rolled carrier tape are achieved.

However, the loading operation of individually clamping the post terminals in the different clamping notches at different positions is completed by an operator, and before the operator clamps the post terminals in the different clamping notches of the carrier tape, the operator needs to take one post terminal from the disordered post terminal stack and adjust the orientation of the taken out post terminal to correctly clamp the post terminals in the clamping notches, which increases the burden of the operator to clamp the post terminals in the different clamping notches of the carrier tape.

Therefore, a cylindrical terminal feeding mechanism capable of automatically feeding cylindrical terminals one by one to reduce the burden and improve the efficiency is urgently needed to overcome the above-mentioned defects.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a can realize the cylindricality terminal feeding mechanism of one by one automatic feeding in order to reduce the burden and raise the efficiency.

In order to realize the above-mentioned purpose, the utility model discloses a cylindricality terminal feed mechanism installs in frame department, including be used for sequencing the vibration dish of carrying one by one to mixed and disorderly cylindricality terminal, be used for accepting cylindricality terminal that the vibration dish carried and make the cylindricality terminal continue the transport cell body of carrying forward and right the cylindricality terminal that the transport cell body carried shifts the material loading gear of material loading, carry the cell body to have towards keeping away from the slope passageway of the direction downward sloping of vibration dish, the material loading gear is followed the direction that the cylindricality terminal was carried to the slope passageway is located carry the front side next door of cell body, a plurality of common edges have been seted up to the periphery of material loading gear's circumference is the accepting tooth's socket that arranges the round equidistantly, every accept the tooth's socket is in material loading gear pivoted in-process rotatory to with the slope passageway is relative material position that connects.

Preferably, the utility model discloses a cylindricality terminal feed mechanism still includes and is used for the restriction jointly accept the cylindricality terminal in the tooth's socket and follows the first lateral stopper and the second lateral stopper of axial float of material loading gear, first lateral stopper and second lateral stopper are followed the direction that the cylindricality terminal was carried to the slope passageway is located carry the front side next door of cell body, first lateral stopper still with the second lateral stopper is followed the axial alignment of material loading gear separates, material loading gear is located partially first lateral stopper with between the second lateral stopper, be in the tooth's socket of accepting the material position still follows material loading gear's axial respectively with first lateral stopper and second lateral stopper align.

Preferably, the first lateral limiting block and the second lateral limiting block are arranged along the circumferential extension of the feeding gear, and the rear ends of the first lateral limiting block and the second lateral limiting block respectively exceed the receiving tooth grooves at the receiving position.

Preferably, a side surface of the first lateral limiting block facing the second lateral limiting block is provided with a plane part perpendicular to the axis of the feeding gear, and a side surface of the second lateral limiting block facing the first lateral limiting block is provided with a plane part perpendicular to the axis of the feeding gear.

Preferably, in the first lateral limiting block, a side surface of the first lateral limiting block facing the second lateral limiting block further has an inclined surface portion located between the planar portion and the conveying trough body, and the inclined surface portion is inclined in a direction away from the second lateral limiting block.

Preferably, in the second lateral limiting block, a side surface of the second lateral limiting block facing the first lateral limiting block further has an inclined surface portion located between the planar portion and the conveying trough body, and the inclined surface portion is inclined in a direction away from the first lateral limiting block.

Preferably, the inclined plane parts are arranged in a central symmetry mode.

Preferably, the side wall of the feeding gear is provided with a circle of avoiding grooves arranged along the circumferential direction of the feeding gear, and the avoiding grooves cut the bearing tooth grooves into two parts.

Compared with the prior art, the conveying groove body is provided with the inclined channel which inclines downwards towards the direction far away from the vibrating disc, the feeding gear is positioned beside the front side of the conveying groove body along the direction of conveying the cylindrical terminal by the inclined channel, the periphery of the feeding gear is provided with a plurality of receiving tooth grooves which are arranged in a circle at equal intervals along the circumferential direction of the feeding gear, and each receiving tooth groove rotates to a material receiving position aligned with the inclined channel in the rotating process of the feeding gear; therefore, in the process that the loading gear drives each bearing tooth groove to rotate to the material receiving position, the vibration disc ensures that the placing position of each cylindrical terminal is correct and orderly conveyed, so that the cylindrical terminals conveyed to the inclined channel by the vibration disc slide into the bearing tooth groove at the material receiving position along the inclined channel, the sequential transfer of the cylindrical terminals to the loading gear is realized, and the placing position of each cylindrical terminal at the loading gear is correct; meanwhile, the cylindrical terminal at the position of the bearing tooth groove is driven by the feeding gear to rotate along with the feeding gear in the rotating process, the cylindrical terminal rotating along with the feeding gear rotates to a feeding position through the feeding gear, so that the cylindrical terminal at the feeding position is clamped in different clamping grooves of the carrier tape, and the purposes of automatically feeding the cylindrical terminals one by one to reduce the burden and improve the efficiency are achieved.

Drawings

Fig. 1 is a perspective view of the cylindrical terminal feeding mechanism of the present invention.

Fig. 2 is a perspective view of the post-shaped terminal feeding mechanism shown in fig. 1 after hiding the vibration plate.

Fig. 3 is an exploded view of fig. 2.

Fig. 4 is a plan view of fig. 2 viewed from above.

Fig. 5 is an internal view taken along line C-C in fig. 4.

Figure 6 is a plan view of figure 4 with the delivery chute body hidden.

Fig. 7 is a plan view of the loading gear of fig. 6 hidden.

Fig. 8 is a perspective view of the feeding gear of the cylindrical terminal feeding mechanism of the present invention.

Detailed Description

In order to explain the technical contents and structural features of the present invention in detail, the following description is made with reference to the embodiments and the accompanying drawings.

Please refer to fig. 1 to 5, the post terminal feeding mechanism 100 of the present invention is installed in the frame 200, and the frame 200 is used for the post terminal feeding mechanism 100 of the present invention to provide the supporting function and the assembling place, and the post terminal feeding mechanism 100 of the present invention comprises a vibrating tray 10 for sequencing and conveying the disordered post terminals 300 one by one, a feeding gear 30 for receiving the post terminals 300 conveyed by the vibrating tray 10 and making the post terminals 300 continue to be conveyed forward and for transferring the post terminals 300 conveyed by the conveying tray 20. The conveying trough body 20 is provided with an inclined channel 21 which is inclined downwards in a direction away from the vibration disk 10, so that the cylindrical terminals 300 conveyed in sequence by the vibration disk 10 can slide to the loading gear 30 more smoothly under the action of gravity of the cylindrical terminals by virtue of the downward inclination of the inclined channel 21; the feeding gear 30 is located beside the front side of the conveying trough body 20 along the direction (i.e. the direction indicated by the arrow a) of conveying the cylindrical terminal 300 along the inclined channel 21, and the periphery of the feeding gear 30 is provided with a plurality of receiving tooth grooves 31 which are arranged in a circle at equal intervals along the circumferential direction of the feeding gear 30, as shown in fig. 8, each receiving tooth groove 31 rotates to a receiving position aligned with the inclined channel 21 during the rotation of the feeding gear 30, as shown in fig. 5, to ensure that each receiving tooth groove 31 can receive the cylindrical terminal 300 slid in by the inclined channel 21. Specifically, in fig. 1 to 6, in order to ensure that the post terminal 300 at the inclined channel 21 slides into the receiving slot 31 reliably and effectively prevent the post terminal 300 in the receiving slot 31 from running along the axial direction of the loading gear 30 (i.e., indicated by the double arrow B) in the process of rotating along the loading gear 30, the post terminal feeding mechanism 100 of the present invention further includes a first lateral stopper 40 and a second lateral stopper 50 which are used together to limit the axial running of the post terminal 300 in the receiving slot 31 along the loading gear 30, the first lateral stopper 40 and the second lateral stopper 50 are located beside the front side of the feed trough body 20 in the direction of feeding the post terminal 300 along the inclined channel 21, the first lateral stopper 40 is further spaced apart from the second lateral stopper 50 in the axial direction of the loading gear 30, while the loading gear 30 is partially located between the first lateral stopper 40 and the second lateral stopper 50, the receiving slot 31 in the receiving position is further aligned with the first lateral stopper 40 and the second lateral stopper 50 in the axial direction of the loading gear 30, that the receiving slot 31 is located in the receiving position, i.e., the receiving slot 31 is located in the receiving position shown in the uppermost view of fig. 6. The feeding gear 30 is partially located between the first lateral limiting block 40 and the second lateral limiting block 50, and the receiving tooth slot 31 at the receiving position is also aligned with the first lateral limiting block 40 and the second lateral limiting block 50 respectively along the axial direction of the feeding gear 30, so as to ensure the reliability of the cylindrical terminal 300 in the receiving tooth slot 31 in subsequent feeding. More specifically, the following:

as shown in fig. 1 to fig. 3, the first lateral stopper 40 and the second lateral stopper 50 are both disposed along the circumferential direction of the loading gear 30, and the rear ends of the first lateral stopper 40 and the second lateral stopper 50 each go beyond the receiving slot 31 of the receiving position, as shown in fig. 6, so as to improve the reliability of sliding the cylindrical terminal 300 at the inclined channel 21 into the receiving slot 31. Specifically, in fig. 7, the side 41 of the first lateral stopper 40 facing the second lateral stopper 50 has a flat portion 411 perpendicular to the axial line of the loading gear 30, and the side 51 of the second lateral stopper 50 facing the first lateral stopper 40 has a flat portion 51 perpendicular to the axial line of the loading gear 30, so that the flat portion 41 and the flat portion 51 are designed to be parallel to each other, ensuring that the distance between the flat portion 41 and the flat portion 51 is the same everywhere, thereby more effectively limiting the cylindrical terminal 300 in the receiving slot 31 from rattling. More specifically, as shown in fig. 6 and 7, in the first lateral stopper 40, the side surface 41 of the first lateral stopper 40 facing the second lateral stopper 50 further has a slope portion 412 located between the planar portion 411 and the feed chute body 20, the slope portion 412 being inclined in a direction away from the second lateral stopper 50; in the second lateral stopper 50, the side 51 of the second lateral stopper 50 facing the first lateral stopper 40 further has a slope portion 512 between the planar portion 511 and the conveying chute body 20, the slope portion 512 being inclined in a direction away from the first lateral stopper 40; preferably, the inclined plane part 412 and the inclined plane part 512 are arranged in a central symmetry manner, so that the space between the side surface 41 and the side surface 51 close to the end of the conveying trough body 20 is enlarged by the arrangement of the inclined plane part 412 and the inclined plane part 512, thereby being more beneficial to the cylindrical terminal 300 on the inclined channel 21 to slide into the receiving tooth slot 31 in the receiving position. In order to avoid the middle part of the cylindrical terminal 300, a circle of avoiding groove 32 is formed in the side wall of the feeding gear 30 along the circumferential direction of the feeding gear 30, and the receiving tooth groove 31 is cut into two parts by the avoiding groove 32; in addition, the receiving slots 31 at the receiving position are aligned with the rear ends of the slope portions 412 (512), respectively, as shown in fig. 7.

Compared with the prior art, the conveying trough body 20 is provided with the inclined channel 21 which inclines downwards in the direction away from the vibrating disk 10, the feeding gear 30 is positioned beside the front side of the conveying trough body 20 along the direction of the inclined channel 21 for conveying the cylindrical terminal 300, the periphery of the feeding gear 30 is provided with a plurality of receiving tooth grooves 31 which are arranged in a circle at equal intervals along the circumferential direction of the feeding gear 30, and each receiving tooth groove 31 rotates to a receiving position aligned with the inclined channel 21 in the rotating process of the feeding gear 30; therefore, in the process that the feeding gear 30 drives each receiving tooth groove 31 to rotate to the receiving position, the vibration disc 10 ensures that the placing position of each cylindrical terminal 300 is correctly and orderly conveyed, so that the cylindrical terminals 300 conveyed to the inclined channel 21 by the vibration disc 10 slide into the receiving tooth grooves at the receiving position along the inclined channel 21, the sequential transfer of the cylindrical terminals 300 to the feeding gear 30 is realized, and the placing position of each cylindrical terminal 300 at the feeding gear 30 is ensured to be correct; meanwhile, the loading gear 30 also drives the cylindrical terminal 300 at the position of the receiving tooth groove 31 to rotate along with the loading gear 30 in the rotating process, and the cylindrical terminal 300 rotating along with the loading gear 30 is rotated to the loading position by the loading gear 30, so that the cylindrical terminal 300 is just clamped in different clamping grooves of the carrier tape when rotating to the loading position, and the purposes of automatically loading the cylindrical terminals 300 one by one to reduce the burden and improve the efficiency are achieved. Or, when the loading gear 30 rotates the post terminals 300 rotating along with it to the loading position, the post terminals 300 at the loading position can be clamped in the clamping grooves of the carrier tape conveyed by the unwinding wheel and the winding wheel cooperatively by a worker, and the post terminals 300 are sequenced one by one and placed correctly without being adjusted by the worker, so the aims of high efficiency and relatively low burden are achieved.

The above disclosure is only a preferred embodiment of the present invention, and the scope of the claims of the present invention should not be limited thereby, and all the equivalent changes made in the claims of the present invention are intended to be covered by the present invention.

Claims

1. The cylindrical terminal feeding mechanism is characterized by comprising a vibrating disc, a conveying groove body and a feeding gear, wherein the vibrating disc is used for sequencing and conveying disordered cylindrical terminals one by one, the conveying groove body is used for receiving the cylindrical terminals conveyed by the vibrating disc and enabling the cylindrical terminals to be conveyed continuously forwards, the feeding gear is used for transferring and feeding the cylindrical terminals conveyed by the conveying groove body, the conveying groove body is provided with an inclined channel inclining downwards towards the direction far away from the vibrating disc, the feeding gear is located beside the front side of the conveying groove body along the direction of conveying the cylindrical terminals by the inclined channel, a plurality of receiving tooth grooves which are arranged into a circle at equal intervals along the circumferential direction of the feeding gear are formed in the periphery of the feeding gear, and each receiving tooth groove rotates to a receiving position aligned with the inclined channel in the rotating process of the feeding gear.

2. The cylindrical terminal feeding mechanism according to claim 1, further comprising a first lateral limiting block and a second lateral limiting block which are used together to limit axial movement of the cylindrical terminal in the receiving tooth slot along the feeding gear, wherein the first lateral limiting block and the second lateral limiting block are located beside a front side of the conveying groove body along a direction of conveying the cylindrical terminal through the inclined channel, the first lateral limiting block and the second lateral limiting block are aligned and spaced along an axial direction of the feeding gear, the feeding gear is partially located between the first lateral limiting block and the second lateral limiting block, and the receiving tooth slot at the receiving position is further aligned with the first lateral limiting block and the second lateral limiting block along the axial direction of the feeding gear.

3. The cylindrical terminal feeding mechanism according to claim 2, wherein the first lateral limiting block and the second lateral limiting block are arranged to extend along a circumferential direction of the feeding gear, and rear ends of the first lateral limiting block and the second lateral limiting block are respectively extended out of the receiving tooth grooves of the receiving position.

4. The cylindrical terminal feeding mechanism according to claim 2, wherein a side of the first lateral stopper facing the second lateral stopper has a flat surface portion perpendicular to an axial line of the feeding gear, and a side of the second lateral stopper facing the first lateral stopper has a flat surface portion perpendicular to an axial line of the feeding gear.

5. The cylindrical terminal feeding mechanism according to claim 4, wherein in the first lateral stopper, a side surface of the first lateral stopper facing the second lateral stopper further has a slope portion located between the planar portion and the feed chute body, the slope portion being inclined in a direction away from the second lateral stopper.

6. The cylindrical terminal feeding mechanism according to claim 5, wherein in the second lateral stopper, a side surface of the second lateral stopper facing the first lateral stopper further has a slope portion between the planar portion and the conveying groove body, the slope portion being inclined in a direction away from the first lateral stopper.

7. The cylindrical terminal feeding mechanism according to claim 6, wherein the inclined surface portions are arranged in a central symmetry.

8. The cylindrical terminal feeding mechanism according to claim 1, wherein a circle of avoiding grooves are formed in the side wall of the feeding gear along the circumferential direction of the feeding gear, and the avoiding grooves cut the receiving tooth grooves into two parts.