CN216710557U

CN216710557U - Production material feeding unit of micromotor shell

Info

Publication number: CN216710557U
Application number: CN202123118564.XU
Authority: CN
Inventors: 陆洁
Original assignee: Jiangsu Chengzhonghe High Precision Steel Pipes Making Co ltd
Current assignee: Jiangsu Chengzhong Intelligent Manufacturing Co ltd
Priority date: 2021-12-13
Filing date: 2021-12-13
Publication date: 2022-06-10
Anticipated expiration: 2031-12-13

Abstract

The utility model discloses a production feeding device for micromotor shells, which comprises a horizontally arranged conveyor belt, wherein the conveyor belt is driven by a motor to periodically rotate in a positive and negative direction alternatively, a guide rail is arranged on the conveyor belt and extends along the length direction of the conveyor belt, and a plurality of tubular micromotor shells are arranged in the guide rail; the outlet end of conveyer belt is provided with horizontal layer board, the upper surface height of horizontal layer board is higher than the upper surface height of conveyer belt, horizontal layer board meets through the ascending inclined plane that one end set up and the outlet end of conveyer belt, the top of horizontal layer board is provided with vertical baffle. The micro-motor shell can be periodically conveyed to a designated position, and the mechanical arm can conveniently grab.

Description

Production material feeding unit of micromotor shell

Technical Field

The utility model relates to the technical field of micromotor shell production, in particular to a feeding device for micromotor shell production.

Background

Micromotors, collectively called "micromotors", refer to motors having a diameter of less than 160mm or a nominal power of less than 750 mW. The shell is the important component of micromotor, the current little motor housing of a pipe form, its field such as mainly being applied to oil pump motor housing, car motor housing, body-building apparatus motor housing and push-down motor housing, this kind of little motor housing of pipe form can use the arm to snatch the shell in order to improve production precision in the production course of working, send the shell into corresponding equipment and process, then take out the shell by the arm again. Correspondingly, the micro-motor shell needs to be manually conveyed to a designated position so as to be convenient for the mechanical arm to grab. However, if workers send the micro-motor housings to the designated positions one by one according to the production cycle of the processing equipment, a large amount of working time of the workers is occupied, and the working efficiency is extremely low. Accordingly, an apparatus is provided that is capable of periodically transporting a micro-machine housing to a designated location.

Disclosure of Invention

The purpose of the utility model is as follows: in order to overcome the defects in the prior art, the utility model provides the production feeding device of the micro motor shell, which can periodically send the micro motor shell to a specified position and is convenient for a mechanical arm to grab.

The technical scheme is as follows: in order to achieve the purpose, the production feeding device for the micromotor shell comprises a horizontally arranged conveying belt, wherein the conveying belt is driven by a motor to rotate periodically in a positive and negative direction alternatively, a guide rail is arranged on the conveying belt, the guide rail extends along the length direction of the conveying belt, and a plurality of tubular micromotor shells are arranged in the guide rail; the outlet end of conveyer belt is provided with horizontal layer board, the upper surface height of horizontal layer board is higher than the upper surface height of conveyer belt, horizontal layer board meets through the ascending inclined plane that one end set up and the outlet end of conveyer belt, the top of horizontal layer board is provided with vertical baffle.

Furthermore, the guide track consists of two longitudinal guide rods arranged at intervals; at least two transverse ejector rods are arranged above the conveyor belt in a spanning mode, and two ends of each transverse ejector rod are fixed to two sides of the conveyor belt through vertical rods; the transverse ejector rod is provided with a transverse sliding rail, a transverse sliding block is arranged in the transverse sliding rail, the lower end of the transverse sliding block is provided with a vertical suspension rod, and the longitudinal guide rod is fixedly connected with the lower end of the corresponding suspension rod; and a first fastening bolt for fixing the position of the transverse sliding block is arranged on the transverse sliding block.

Furthermore, longitudinal slide rails are respectively arranged on two sides of the horizontal supporting plate, longitudinal slide blocks are respectively arranged on two sides of the vertical baffle, and the longitudinal slide blocks are in sliding fit with the corresponding longitudinal slide rails; and a second fastening bolt for fixing the longitudinal sliding block is arranged on the longitudinal sliding block.

Furthermore, a through groove extending transversely is formed in the vertical baffle, and one end of the longitudinal guide rod longitudinally penetrates through the through groove.

Furthermore, a plurality of groups of guide rails are transversely arranged on the conveyor belt, and the end parts of a plurality of longitudinal guide rods in the plurality of groups of guide rails penetrate through the through grooves.

Furthermore, two sides of the transverse ejector rods, which face the inlet and outlet ends of the conveyor belt, are respectively provided with a transverse sliding rail, and a plurality of transverse sliding blocks positioned on the same transverse ejector rod are alternately arranged on the transverse sliding rails on two sides of the transverse ejector rod.

Has the advantages that: according to the production feeding device for the micro-motor shells, the plurality of micro-motor shells are arranged on the conveying belt along the guide rail, when the conveying belt rotates in the forward direction, the outermost micro-motor shell is extruded to the horizontal supporting plate and limited by the vertical baffle, and when the conveying belt rotates in the reverse direction, the outermost micro-motor shell is left on the horizontal supporting plate and is separated from the adjacent micro-motor shells by a certain distance, so that a mechanical arm can conveniently grab the outermost micro-motor shell.

Drawings

FIG. 1 is a schematic structural diagram of a production feeding device of the present invention;

FIG. 2 is a schematic view of a horizontal pallet and a rising ramp;

FIG. 3 is a schematic view of the arrangement of the micro-motor housing during forward rotation of the conveyor belt;

figure 4 is a schematic view of the arrangement of the microcomputer housing when the conveyor belt is rotating in the reverse direction.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

The feeding device for producing the micro motor shell as shown in fig. 1 to 4 comprises a horizontally arranged conveyor belt 1, wherein the conveyor belt 1 is driven by a motor 18 to rotate periodically in forward and reverse directions alternately, as shown in fig. 3 and 4, in a single period, the forward rotation time of the conveyor belt 1 is longer than the reverse rotation time, so that the displacement generated by the forward rotation of the conveyor belt 1 is larger than the displacement generated by the reverse rotation, and the subsequent micro motor shell 3 can be extruded onto a horizontal supporting plate 4.

The conveyor belt 1 is provided with a guide rail 2, the guide rail 2 horizontally extends along the length direction of the conveyor belt 1, as shown in fig. 3 and 4, and a plurality of tubular micromotor housings 3 are arranged in the guide rail 2. The outlet end of the conveyor belt 1 is provided with a horizontal supporting plate 4, and the outlet end of the conveyor belt 1 is the end towards which the micromotor shell 3 moves when the conveyor belt 1 rotates in the forward direction. The height of the upper surface of the horizontal supporting plate 4 is higher than that of the upper surface of the conveying belt 1, and the horizontal supporting plate 4 is connected with the outlet end of the conveying belt 1 through a rising inclined surface 5 arranged at one end. When the conveyor belt 1 rotates in the forward direction, the micromotor shell 3 at the outermost end moves to the horizontal supporting plate 4 along the ascending inclined surface 5, and the horizontal supporting plate 4 is higher than the conveyor belt 1, so that when the conveyor belt 1 rotates in the reverse direction, the micromotor shell 3 on the horizontal supporting plate 4 cannot move in the reverse direction along with the conveyor belt 1. And a vertical baffle 6 is arranged above the horizontal supporting plate 4, the vertical baffle 6 limits the micromotor shell 3, and the distance between the vertical baffle 6 and the end part of the ascending inclined plane 5 is smaller than the diameter of the micromotor shell 3.

The guide rail 2 is composed of two longitudinal guide rods 7 arranged at intervals. At least two transverse ejector rods 8 are arranged above the conveyor belt 1 in a spanning mode, and two ends of each transverse ejector rod 8 are fixed to two sides of the conveyor belt 1 through vertical rods 9. The horizontal ejector rod 8 is provided with a horizontal sliding rail 10, a horizontal sliding block 11 is arranged in the horizontal sliding rail 10, the lower end of the horizontal sliding block 11 is provided with a vertical hanging rod 12, and the longitudinal guide rod 7 is fixedly connected with the lower end of the corresponding hanging rod 12. The transverse sliding block 11 is provided with a first fastening bolt 13 for fixing the position of the transverse sliding block, and the distance between the two longitudinal guide rods 7 can be adjusted by moving the transverse sliding block 11 and rotating the first fastening bolt 13, so that the width of the guide rail 2 is adjusted to adapt to micromotor shells 3 of different specifications, and the universality is improved.

The two sides of the horizontal supporting plate 4 are respectively provided with a longitudinal slide rail 14, the two sides of the vertical baffle 6 are respectively provided with a longitudinal slide block 15, and the longitudinal slide blocks 15 are in sliding fit with the corresponding longitudinal slide rails 14. The longitudinal slide block 15 is provided with a second fastening bolt 17 for fixing the position of the longitudinal slide block. The distance between the vertical baffle 6 and the end part of the ascending inclined plane 5 can be adjusted by moving the longitudinal slide block 15 and rotating the second fastening bolt 17 so as to adapt to the micromotor shells 3 with different specifications and improve the general applicability.

A through groove 16 extending transversely is formed in the vertical baffle 6, and one end of the longitudinal guide rod 7 longitudinally penetrates through the through groove 16. As shown in fig. 1, when the micromotor housing 3 is positioned on the horizontal support plate 4, the longitudinal guide rods 7 can limit the two sides of the housing.

A plurality of groups of guide rails 2 are transversely arranged on the conveyor belt 1, and the end parts of a plurality of longitudinal guide rods 7 in the plurality of groups of guide rails 2 all penetrate through the through grooves 16. In practical application, the mechanical arm can move along the width direction of the conveyor belt 1, so that the mechanical arm can periodically grab the micromotor shells 3 on the plurality of groups of guide rails 2 in sequence. The setting of multiunit guide rail 2 can utilize the space on the conveyer belt 1 more fully, and the workman can once only be arranged micromotor shell 3 in multiunit guide rail 2 in addition, needn't send into little micromotor shell 3 assigned position one by one according to the production cycle of processing equipment, and work efficiency is higher.

The two sides of the transverse ejector rods 8 facing the inlet and outlet ends of the conveyor belt 1 are respectively provided with a transverse sliding rail 10, and a plurality of transverse sliding blocks 11 positioned on the same transverse ejector rod 8 are alternately arranged on the transverse sliding rails 10 on the two sides of the transverse ejector rod 8, so that the distance between the adjacent hanging rods 12 can be smaller, and the adjustable range of the width of the guide track 2 is larger.

The working mode of the utility model is as follows: the workman puts a plurality of micromotor shells 3 to each guide rail 2 in, 1 forward rotations of conveyer belt, extrude to horizontal layer board 4 with the micromotor shell 3 of outermost end on, then 2 reverse rotations of conveyer belt, micromotor shell 3 of outermost end is stayed on horizontal layer board 4 and is separated with adjacent shell, make things convenient for the robotic arm to snatch the shell of staying on horizontal layer board 4, then 2 forward rotations once more of conveyer belt, 2 forward rotations's of conveyer belt displacement will be greater than reverse rotation, so that follow-up micromotor shell 4 is crowded to be supplemented on horizontal layer board 4.

The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the utility model and these are intended to be within the scope of the utility model.

Claims

1. The utility model provides a production material feeding unit of micromotor shell which characterized in that: the conveying belt device comprises a conveying belt (1) which is horizontally arranged, wherein the conveying belt (1) is driven by a motor (18) to rotate periodically in a positive and negative direction in an alternating manner, a guide track (2) is arranged on the conveying belt (1), the guide track (2) extends along the length direction of the conveying belt (1), and a plurality of tubular micro motor shells (3) are arranged in the guide track (2);

the exit end of conveyer belt (1) is provided with horizontal layer board (4), the upper surface height of horizontal layer board (4) is higher than the upper surface height of conveyer belt (1), horizontal layer board (4) meet with the exit end of conveyer belt (1) through ascending inclined plane (5) that one end set up, the top of horizontal layer board (4) is provided with vertical baffle (6).

2. The feeding device for producing micromotor housings according to claim 1, characterized in that: the guide track (2) consists of two longitudinal guide rods (7) arranged at intervals; at least two transverse ejector rods (8) are arranged above the conveyor belt (1) in a spanning mode, and two ends of each transverse ejector rod (8) are fixed to two sides of the conveyor belt (1) through vertical rods (9); a transverse sliding rail (10) is arranged on the transverse ejector rod (8), a transverse sliding block (11) is arranged in the transverse sliding rail (10), a vertical hanging rod (12) is arranged at the lower end of the transverse sliding block (11), and the longitudinal guide rod (7) is fixedly connected with the lower end of the corresponding hanging rod (12); and a first fastening bolt (13) for fixing the position of the transverse sliding block (11) is arranged on the transverse sliding block.

3. The feeding device for producing micromotor housings according to claim 2, characterized in that: longitudinal slide rails (14) are respectively arranged on two sides of the horizontal supporting plate (4), longitudinal slide blocks (15) are respectively arranged on two sides of the vertical baffle (6), and the longitudinal slide blocks (15) are in sliding fit with the corresponding longitudinal slide rails (14); and a second fastening bolt (17) for fixing the longitudinal slide block (15) is arranged on the longitudinal slide block.

4. The micro-machine housing production feed assembly of claim 3, wherein: a through groove (16) extending transversely is formed in the vertical baffle (6), and one end of the longitudinal guide rod (7) longitudinally penetrates through the through groove (16).

5. The micro-machine housing production feed assembly of claim 4, wherein: a plurality of groups of guide rails (2) are transversely arranged on the conveyor belt (1), and the end parts of a plurality of longitudinal guide rods (7) in the plurality of groups of guide rails (2) all penetrate through the through grooves (16).

6. The feeding device for producing the micromotor housing according to claim 5, wherein: the two sides of the transverse ejector rod (8) facing the inlet and outlet ends of the conveyor belt (1) are respectively provided with a transverse sliding rail (10), and a plurality of transverse sliding blocks (11) positioned on the same transverse ejector rod (8) are alternately arranged on the transverse sliding rails (10) on the two sides of the transverse ejector rod (8).