CN213036701U

CN213036701U - Conveying structure of electronic component production line

Info

Publication number: CN213036701U
Application number: CN202021557151.4U
Authority: CN
Inventors: 王建平
Original assignee: Jiangsu Electric Power Equipment Co ltd
Current assignee: Jiangsu Electric Power Equipment Co ltd
Priority date: 2020-07-31
Filing date: 2020-07-31
Publication date: 2021-04-23
Anticipated expiration: 2030-07-31

Abstract

The utility model discloses a conveying structure of electronic components production line, including material way, whirl baffle and guide plate, the inboard that the material was said is connected with the swash plate, and the adjacent whirl baffle that has in middle part of swash plate, whirl baffle's one end is connected with the rotation axis, and the front end of rotation axis is connected with the rocker, the one end of rocker is connected with the crank. This rotation axis passes through the rocker and constitutes swing joint with the crank, and rotation axis and crank are perpendicular form with the rocker and distribute, and rocker and crank pass through the rotation axis and constitute revolution mechanic, the rotation axis has the design of rocker and crank to adopt the ergonomic design, at the in-process of holding the crank, it is rotatory with the rotation axis to drive the rocker under the effort of torsion, this structure is more reasonable, reduce human intensity of labour, the person of facilitating the use uses, revolution mechanic can make the rotation axis rotatory rotation that drives rotating barrier, thereby the quantity of control material whereabouts, accomplish the transmission rate of accurately control material.

Description

Conveying structure of electronic component production line

Technical Field

The utility model relates to an electronic components production technical field specifically is a transport structure of electronic components production line.

Background

Electronic components, which are basic elements of electronic circuits, are usually packaged individually and have two or more leads or metal contacts, and are connected to each other to form an electronic circuit with specific functions, such as: amplifiers, radio receivers, oscillators, etc., one of the common ways to connect electronic components, perhaps individual packages (resistors, capacitors, inductors, transistors, diodes, etc.), or groups of various complexities, such as: integrated circuits (operational amplifiers, exclusion, logic gates, etc.).

The conveying structure in the market does not solve the problems of uniform placement of materials in the conveying process and control of the material input amount of the conveying structure to control the quantity of the conveyed materials, and therefore, the conveying structure of the electronic component production line is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a conveying structure of electronic components production line to the problem of the material quantity that the material input volume that does not solve the even placing of material in the data send process and control transmission structure who proposes among the above-mentioned background art controls the conveying is solved.

In order to achieve the above object, the utility model provides a following technical scheme: a conveying structure of an electronic component production line comprises a material channel, a rotating baffle and a material guide plate, wherein an inclined plate is connected to the inner side of the material channel, the rotating baffle is arranged close to the middle of the inclined plate, a rotating shaft is connected to one end of the rotating baffle, a rocker is connected to the front end of the rotating shaft, a crank is connected to one end of the rocker, a base station is distributed at the lower end of the material channel, a first hydraulic rod is connected to the upper end of one side of the base station, a material pushing disc head is connected to one end of the first hydraulic rod, a first conveying supporting column is connected to the upper end of the base station, a first transmission shaft is connected to the inner side of the first conveying supporting column, a first conveying belt is connected to the outer side of the middle of the first transmission shaft, a second conveying belt is arranged close to the inner side of the first transmission shaft, a second transmission shaft wraps one end of the second conveying belt, and a, the front end middle part of second transmission shaft is provided with the second support column, one side lower extreme of third conveyer belt distributes and has the pneumatic cylinder, and the upper end of pneumatic cylinder is connected with the hydraulic pressure pipe, the upper end middle part of hydraulic pressure pipe is connected with the second hydraulic pressure pipe, and the upper end of second hydraulic pressure pipe is connected with hydraulic pressure and holds in the palm, the upper end that hydraulic pressure held in the palm is connected with the layer board, and the upper end of layer board hugs closely and has connect the material basin.

Preferably, the rotating shaft and the crank form a movable connection through the rocker, the rotating shaft, the crank and the rocker are vertically distributed, and the rocker and the crank form a rotating structure through the rotating shaft.

Preferably, the material pushing disc head and the first hydraulic rod are distributed vertically, and the first hydraulic rod and the base platform form a stretching structure.

Preferably, the object guide plate and the third conveying belt are distributed vertically, and one side of the material pushing pan head is distributed along the tangent line of the second transmission shaft.

Preferably, the hydraulic support, the second hydraulic pipe and the hydraulic pipe are distributed in a vertical shape, and the second hydraulic pipe and the hydraulic pipe form a hydraulic lifting structure.

Preferably, the material pushing pan head, the material receiving basin, the material guide plate and the third conveying belt are distributed in a horizontal shape, and five material receiving basins are arranged.

Compared with the prior art, the beneficial effects of the utility model are that: the rotating shaft is movably connected with the crank through the rocker, the rotating shaft, the crank and the rocker are vertically distributed, the rocker and the crank form a rotating structure through the rotating shaft, the rotating shaft is provided with the rocker and the crank, the design of the rocker and the crank adopts the human engineering design, and the rocker and the rotating shaft are driven to rotate under the action of torsion force in the process of holding the crank, so that the structure is more reasonable, the labor intensity of a human body is reduced, the use by a user is facilitated, the rotating structure can enable the rotating shaft to rotate to drive the rotating baffle to rotate, the falling quantity of materials is controlled, and the transmission rate of the materials is accurately controlled;

the material pushing disc head and the first hydraulic rod are vertically distributed, the first hydraulic rod and the base station form a stretching structure, materials can be successfully received by the material receiving basin through the stretching structure, and the materials can be regularly and uniformly transported, so that the transportation continuity is increased, and the transportation of the materials is convenient;

the object guide plate and the third conveying belt are vertically distributed, one side of the material pushing pan head is distributed along a tangent line of the second transmission shaft, the object guide plate can enable the material receiving basin which moves at a constant speed to move continuously, so that an operator has enough reaction time, the materials can be stored more smoothly, and the risk caused by mutual extrusion and contact of the materials is reduced.

Drawings

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

FIG. 2 is a schematic top view of the present invention;

fig. 3 is a schematic view of the structure for controlling the flow rate in a top view.

In the figure: 1. a material channel; 2. a sloping plate; 3. rotating the baffle; 4. a rotating shaft; 5. a rocker; 6. a crank; 7. a base station; 8. a first transport support column; 9. a first drive shaft; 10. a first hydraulic lever; 11. a material pushing pan head; 12. a first conveyor belt; 13. a hydraulic cylinder; 14. a hydraulic tube; 15. a second hydraulic pipe; 16. Hydraulic support; 17. a support plate; 18. a second conveyor belt; 19. a guide plate; 20. a second drive shaft; 21. A third conveyor belt; 22. a second support column; 23. a material receiving basin.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a conveying structure of an electronic component production line comprises a material channel 1, an inclined plate 2, rotary baffle plates 3, a rotary shaft 4, a rocker 5, a crank 6, a base 7, a first conveying support column 8, a first transmission shaft 9, a first hydraulic rod 10, a material pushing disc head 11, a first conveying belt 12, a hydraulic cylinder 13, a hydraulic pipe 14, a second hydraulic pipe 15, a hydraulic support 16, a support plate 17, a second conveying belt 18, a material guide plate 19, a second transmission shaft 20, a third conveying belt 21, a second support column 22 and a material receiving basin 23, wherein the inclined plate 2 is connected to the inner side of the material channel 1, the rotary baffle plates 3 are arranged in the middle of the inclined plate 2, the rotary baffle plates 3 are connected to one end of the rotary baffle plates 4, the rocker 5 is connected to the front end of the rotary shaft 4, the crank 6 is connected to one end of the rocker 5, the base 7 is distributed at the lower end of the material channel 1, the upper end of one side of the base 7 is, the upper end of the base table 7 is connected with a first transmission supporting column 8, the inner side of the first transmission supporting column 8 is connected with a first transmission shaft 9, the outer side of the middle of the first transmission shaft 9 is connected with a first transmission belt 12, the inner side of the first transmission shaft 9 is adjacent to a second transmission belt 18, one end of the second transmission belt 18 is wrapped with a second transmission shaft 20, the outer side of the front end of the second transmission shaft 20 is adjacent to a third transmission belt 21, the middle of the front end of the second transmission shaft 20 is provided with a second supporting column 22, the lower end of one side of the third transmission belt 21 is distributed with a hydraulic cylinder 13, the upper end of the hydraulic cylinder 13 is connected with a hydraulic pipe 14, the middle of the upper end of the hydraulic pipe 14 is connected with a second hydraulic pipe 15, the upper end of the second hydraulic pipe 15 is connected with a hydraulic support 16;

the rotating shaft 4 is movably connected with the crank 6 through the rocker 5, the rotating shaft 4, the crank 6 and the rocker 5 are vertically distributed, the rocker 5 and the crank 6 form a rotating structure through the rotating shaft 4, the rotating shaft 4 is provided with the rocker 5 and the crank 6 which are designed in an ergonomic way, the rocker 5 and the rotating shaft 4 are driven to rotate under the action of torsion in the process of holding the crank 6, the structure is more reasonable, the labor intensity of a human body is reduced, the use by a user is facilitated, the rotating structure can enable the rotating shaft 4 to rotate to drive the rotating baffle 3 to rotate, so that the falling quantity of materials is controlled, and the transmission rate of the materials is accurately controlled;

the material pushing disc head 11 and the first hydraulic rod 10 are vertically distributed, the first hydraulic rod 10 and the base station 7 form a stretching structure, materials can be successfully received by the material receiving basin 23 through the stretching structure, and the materials can be regularly and uniformly transported, so that the transportation continuity is increased, and the transportation of the materials is convenient;

the object guide plate 19 and the third conveying belt 21 are vertically distributed, one side of the material pushing pan head 11 is distributed at a tangent position along the second transmission shaft 20, and the object guide plate 19 can enable the material receiving basin 23 which moves at a constant speed to move continuously, so that an operator has enough reaction time, the materials are stored more smoothly, and the risk caused by mutual extrusion and contact of the materials is reduced;

the hydraulic support 16, the second hydraulic pipe 15 and the hydraulic pipe 14 are distributed vertically, the second hydraulic pipe 15 and the hydraulic pipe 14 form a hydraulic lifting structure, continuous transportation can be facilitated due to the arrangement, meanwhile, the transmission work of the material receiving basin 23 can be continuously performed due to the stretching structure, and the transportation can not be interfered by the material receiving basin 23;

the material pushing pan head 11, the material receiving basin 23, the material guide plate 19 and the third conveying belt 21 are distributed horizontally, five material receiving basins 23 are arranged, the horizontal distribution enables transportation to be carried out at a constant speed smoothly, and meanwhile five material receiving basins 23 are arranged, so that the space occupied by the material receiving basin 23 and equipment and energy consumption can be utilized to the maximum extent;

the working principle is as follows: for the transmission structure of the electronic component production line, firstly processed materials fall between the inclined plate 2 and the rotary baffle 3 from the material channel 1, the rocker 5 is manually shaken to push the operation rocker 5 to rotate, so that the rotary baffle 3 and the rotary shaft 4 rotate, the falling of the materials is limited and controlled by manually rotating the crank 6, at this time, a gap appears between the inclined plate 2 and the rotary baffle 3, the materials successfully fall onto the first transmission belt 12 from the gap, the materials falling onto the first transmission belt 12 are driven by the rotating first transmission shaft 9 to move towards the direction of the object guide plate 19, in the process of driving the materials, the base 7 and the hydraulic rod 10 form a stretching structure, so that the material pushing disc head 11 pushes the material receiving basin 23 to move towards the same direction of the materials, the materials fall into the material receiving basin 23 at one end passing through the first transmission belt 12, then the material receiving basin 23 is continuously pushed by the material pushing pan head 11, the material on the first conveying belt 12 continuously falls, so that the material is uniformly distributed on the material receiving basin 23, the material receiving basin 23 is conveyed to the third conveying belt 21 due to the slope of the material guide plate 19, the third conveying belt 21 continuously drives the material receiving basin 23 and the material thereon, the material pushing pan head 11 is also quickly drawn back, so that the material pushing pan head 11 continuously pushes the material receiving basin 23 to perform material receiving work, the material receiving basin 23 on the third conveying belt 21 is driven, and finally the material receiving basin 23 on one end of the whole equipment is supported by the supporting plate 17 on one end of the equipment, along with the movement of the material receiving basin 23, the material receiving basin 23 in the middle of the equipment is transferred to one end, the hydraulic pipe 14, the second hydraulic pipe 15 and the hydraulic support 16 in the middle of the equipment upwards support the material receiving basin 23, the hydraulic pipe 14, the second hydraulic pipe 15 and the hydraulic support 16 at one end of the equipment fall, so that more material receiving basins 23 are transferred, the staff only need with the equipment middle part connect the basin 23 constantly change, with constantly take off from equipment one end connect the basin 23 with the material and can accomplish the transmission of finished product material, and have the drive of second conveyer belt 18 for be in same power in the equipment transmission process, and keep at the uniform velocity.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a conveying structure of electronic components production line, includes material way (1), rotating barrier (3) and leads thing board (19), its characterized in that: the material conveying device is characterized in that an inclined plate (2) is connected to the inner side of a material channel (1), a rotary baffle (3) is arranged next to the middle of the inclined plate (2), one end of the rotary baffle (3) is connected with a rotary shaft (4), the front end of the rotary shaft (4) is connected with a rocker (5), one end of the rocker (5) is connected with a crank (6), base platforms (7) are distributed at the lower end of the material channel (1), a first hydraulic rod (10) is connected to the upper end of one side of each base platform (7), a material pushing disc head (11) is connected to one end of each first hydraulic rod (10), a first conveying support column (8) is connected to the upper end of each base platform (7), a first transmission shaft (9) is connected to the inner side of the first conveying support column (8), a first transmission belt (12) is connected to the outer side of the middle of the first transmission shaft (9), and a second transmission belt (, the one end parcel of second conveyer (18) has second transmission shaft (20), and the front end outside of second transmission shaft (20) is adjacent to have third conveyer (21), the front end middle part of second transmission shaft (20) is provided with second support column (22), one side lower extreme distribution of third conveyer (21) has pneumatic cylinder (13), and the upper end of pneumatic cylinder (13) is connected with hydraulic pressure pipe (14), the upper end middle part of hydraulic pressure pipe (14) is connected with second hydraulic pressure pipe (15), and the upper end of second hydraulic pressure pipe (15) is connected with hydraulic pressure and holds in the palm (16), the upper end that hydraulic pressure held in the palm (16) is connected with layer board (17), and the upper end of layer board (17) is hugged closely and is had and connect material basin (23).

2. A transfer structure of an electronic component production line as claimed in claim 1, characterized in that: rotation axis (4) constitute swing joint through rocker (5) and crank (6), and rotation axis (4) and crank (6) are vertical form with rocker (5) and distribute to rocker (5) and crank (6) constitute revolution mechanic through rotation axis (4).

3. A transfer structure of an electronic component production line as claimed in claim 1, characterized in that: the material pushing disc head (11) and the first hydraulic rod (10) are distributed vertically, and the first hydraulic rod (10) and the base platform (7) form a stretching structure.

4. A transfer structure of an electronic component production line as claimed in claim 1, characterized in that: the object guide plate (19) and the third conveying belt (21) are vertically distributed, and one side of the material pushing disc head (11) is distributed along the tangent line of the second transmission shaft (20).

5. A transfer structure of an electronic component production line as claimed in claim 1, characterized in that: the hydraulic support (16), the second hydraulic pipe (15) and the hydraulic pipe (14) are distributed in a vertical shape, and the second hydraulic pipe (15) and the hydraulic pipe (14) form a hydraulic lifting structure.

6. A transfer structure of an electronic component production line as claimed in claim 1, characterized in that: the material pushing pan head (11), the material receiving basin (23), the material guide plate (19) and the third conveying belt (21) are distributed in a horizontal shape, and five material receiving basins (23) are arranged.