CN220055499U - Air-blowing feeding assembly - Google Patents

Abstract

An air-blowing feeding assembly comprises a feeding disc assembly, a blowing assembly and a vibration lifting assembly. The feeding disc assembly comprises a disc body, at least one roller track, at least four supporting columns and a gap structure arranged between the disc body and each supporting column. The blowing component comprises an air guide pipe. At least one air guide pipe is arranged on one side of each roller track. The vibration lifting component vibrates along the vertical direction so as to shake a workpiece arranged at the top of the roller track away from the roller track, and the blowing component blows air so as to blow the workpiece along the direction of the roller track. This air-blowing material loading subassembly is through setting up the subassembly of blowing, and vibration lifting subassembly. Firstly, the vibration lifting component vibrates the workpiece in the vertical direction, and then the blowing component blows along the extending direction of the roller track, so that the vibrated workpiece is blown into the accommodating groove.

Description

Air-blowing feeding assembly

Technical Field

The utility model belongs to the technical field of workpiece feeding, and particularly relates to an air-blowing feeding assembly.

Background

In the production process of workpieces, the workpieces are essentially required to be transferred from one place to another for processing, and the existing transfer mode is often to transfer through a conveyor belt: the work piece is placed on the conveyer belt top in proper order to along with the conveyer belt is sent to the terminal work piece of conveyer belt and is acceptd the bench, is provided with the recess of clamping a work piece just on the work piece acceptd the bench, after a work piece is transported to in the recess, the conveyer belt will stop running, and a manipulator will be transferred the work piece in the recess to next processing position and process, accomplishes a cycle.

However, since the conveyor belt will stop running after feeding one workpiece into the groove each time, this will make the time for each start of the conveyor belt very short, and repeated start and stop will reduce the service life of the conveyor belt.

Disclosure of Invention

In view of the above, the present utility model provides an air-blown feeding assembly to solve the above problems.

The utility model provides an air-blowing material loading subassembly, it includes a horizontal setting's material loading tray subassembly, one sets up the subassembly of blowing at material loading tray subassembly top, and one sets up the vibration lifting subassembly of material loading tray subassembly bottom. The feeding disc assembly comprises a disc body, at least one roller track arranged at the top of the disc body, at least four supporting columns arranged at the bottom of the disc body, and a gap structure arranged between the disc body and each supporting column. The blowing component comprises an air guide pipe with the air outlet direction being consistent with the track direction of the roller. At least one air guide pipe is arranged on one side of each roller track. The workpiece is placed on top of the roller track. The vibratory lifting assembly vibrates in a vertical direction to shake a workpiece disposed on top of the roller track off the roller track. The blowing component blows air so as to blow the workpiece along the track direction of the roller, so that the workpiece can be moved.

Further, each gap structure comprises a U-shaped buckle arranged at the bottom of the feeding disc assembly, two side walls of the U-shaped buckle, which are downward in opening and are provided with stop blocks respectively, the side surface of the support column is close to the top end of the support column, an annular groove is formed in the position, close to the top end of the support column, and the tail end of the support column is clamped in the U-shaped buckle so that the annular groove corresponds to the stop block.

Further, each U-shaped buckle of the gap structure on the feeding disc assembly is provided with at least two mounting directions, and an included angle is formed between the same side surfaces of the U-shaped buckles, so that the feeding disc assemblies are limited to deviate from the top ends of the support columns due to horizontal displacement caused by vibration.

Further, one end of the feeding disc assembly is provided with a workpiece accommodating table, the workpiece accommodating table comprises an accommodating seat, an accommodating groove, at least one roller and a first sensor, the accommodating seat is arranged corresponding to each roller rail, the roller is arranged at the bottom of each accommodating groove, the first sensor is inserted into one side of each accommodating groove, and the accommodating groove is communicated with the corresponding roller rail.

Further, the top of material loading tray subassembly is provided with prevents that the work piece from roller bearing track top deviate from limit structure, limit structure includes two edges roller bearing track extending direction sets up and is located the outer baffle of material loading tray subassembly both sides, works as when the orbital quantity of roller bearing is two at least, limit structure is still including setting up along roller bearing track extending direction sets up and be located two adjacent the interior baffle between the roller bearing track, outer baffle with interior baffle respectively with disk body parallel arrangement, outer baffle with the projection of interior baffle on the horizontal plane all falls in adjacent in the roller bearing track.

Further, the bottom of material loading tray subassembly is provided with and is used for controlling material loading tray subassembly inclination's angle adjustment device, the support column is scalable, angle adjustment device includes a root edge the installation pole that roller bearing track direction set up sets up respectively the altitude mixture control U-shaped piece at installation pole both ends to and a fixed rotating block, vibration lifting subassembly sets up the installation pole with between the disk body, the altitude mixture control U-shaped piece with fixed rotating block is fixed the setting respectively in the bottom surface, fixed rotating block is close to the orbital discharge end of roller bearing, the one end cartridge of installation pole is in the altitude mixture control U-shaped piece, vertical groove has been seted up respectively at the both ends of altitude mixture control U-shaped piece, every be provided with an adjusting bolt in the vertical groove respectively, in order to selectively will the one end of installation pole is fixed at different altitudes.

Further, the number of the roller tracks is 4.

Further, the air guide pipe is arranged at the top of the inner baffle plate or the outer baffle plate on the adjacent side of the roller track, and the air guide pipe is detachably connected with the inner baffle plate and the outer baffle plate through bolts.

Further, one side of each roller track is provided with a workpiece feeding sensor respectively, and the workpiece feeding sensors are infrared sensors and detect light rays perpendicular to the roller tracks.

Further, a feeding baffle plate is arranged at the feeding end of the feeding disc assembly, the feeding baffle plate is vertically arranged, a positioning hole for a workpiece to pass through is formed in the position of each feeding baffle plate corresponding to the track of the roller, and a feeding guide plate is arranged on the end face of each feeding baffle plate.

Compared with the prior art, the air-blowing feeding assembly provided by the utility model has the advantages that the air-blowing assembly and the vibration lifting assembly are arranged, the vibration lifting assembly vibrates the workpiece in the vertical direction, and then the air-blowing assembly blows along the extending direction of the roller track, so that the vibrated workpiece is blown into the accommodating groove.

Drawings

Fig. 1 is a schematic structural diagram of an air-blown feeding assembly provided by the utility model.

Fig. 2 is an enlarged view of a portion of the air-blown feed assembly of fig. 1 at a.

Fig. 3 is a side view of the air blown feed assembly of fig. 1.

Fig. 4 is a left side view of the air blown feed assembly of fig. 1.

Fig. 5 is a partial enlarged view of the air-blown feed assembly of fig. 1 at B.

Detailed Description

Specific embodiments of the present utility model are described in further detail below. It should be understood that the description herein of the embodiments of the utility model is not intended to limit the scope of the utility model.

Fig. 1 to 5 are schematic structural views of an air-blown feeding assembly according to the present utility model. The air-blowing feeding assembly comprises a feeding disc assembly 10, a blowing assembly 20 arranged at the top of the feeding disc assembly 10, and an angle adjusting device 30 arranged at the bottom of the feeding disc assembly 10. The air-blowing feeding assembly further comprises other functional modules, such as a distribution box for power supply, etc., which should be known to those skilled in the art, and will not be described in detail herein.

The feeding tray assembly 10 comprises a tray body 11 horizontally arranged, at least one roller rail 12 arranged at the top of the tray body 11, at least four supporting columns 13 arranged at the bottom of the tray body 11, a gap structure 14 arranged between the tray body 11 and each supporting column 13, a limiting mechanism 15 arranged at the top of the tray body 11, a feeding baffle 16 arranged at the feeding end of the roller rail 12, a feeding guide plate 17 arranged at the end face of the feeding baffle 16, a workpiece accommodating table 18 arranged at the discharging end of the roller rail 12, and a vibration lifting assembly 19 arranged at the bottom of the tray body 11. In this embodiment, the number of roller tracks 12 is four. Each gap structure 14 includes an annular groove 141 disposed on a side surface of each support column 13 and near a top end, and a U-shaped buckle 142 disposed at a bottom of the tray 11 and corresponding to each support column 13. The opening of the U-shaped buckle 142 is downward, and one stop block 143 is respectively disposed on opposite sides of two sidewalls of the U-shaped buckle. The end of the support column 13 extends into the U-shaped buckle 142, and the stop 143 is matched with the annular groove 141, so that the support column 13 is clamped in the U-shaped buckle 142. The U-shaped buckle 142 limits displacement of the tray 11 and the support column 13 in a certain direction in the horizontal direction. The height of the annular groove 141 is greater than that of the stop block 143, and the tail end of the support column 13 and the bottom of the U-shaped buckle 143 are arranged at intervals, so that when the tray 11 vibrates, the tray 11 can move up and down at the tail end of the support column 13, and the displacement is controlled by the interval between the tail end of the support column 13 and the U-shaped buckle 143 or by the height difference between the annular groove 141 and the stop block 143.

The limiting mechanism 15 includes two outer baffles 151 disposed along the extending direction of the roller rail 12 and located at two sides of the upper tray assembly 10. In this embodiment, since the number of the roller tracks 12 is 4, the limiting structure 15 further includes an inner baffle 152 disposed along the extending direction of the roller tracks 12 and located between two adjacent roller tracks 12. The outer baffle 151 and the inner baffle 152 are respectively parallel to the tray 11, and are respectively spaced from the roller tracks 11. The projections of the outer baffle plate 151 and the inner baffle plate 152 on the horizontal plane fall in the adjacent roller tracks 12, so that the workpiece is not easy to deviate from the adjacent inner baffle plate 152 or the gap between the adjacent inner baffle plate 152 and the outer baffle plate 151, and the limiting effect is achieved.

The feed baffle 16 is vertically disposed at the feed end of the roller track 12. At least one feeding hole 161 is formed in the side surface of the feeding baffle 16 corresponding to the position of each roller track 12. The workpiece enters the roller track 12 through the feed port 161. The end face of the feed baffle 16 is provided with a feed guide plate 17. The workpiece is first placed on top of the feed guide plate 17 and enters the roller rail 12 through the feed port 161 under the operation of an operator.

The workpiece accommodating table 18 includes an accommodating seat 181, an accommodating groove 182 provided corresponding to each roller rail 12, at least one roller 183 provided at a bottom of each accommodating groove 182, and a first sensor 183 inserted at one side of each accommodating groove 182. The receiving slots 182 are in communication with the corresponding roller track 12. The first sensor 184 senses the distance between the workpiece and the sensor, so as to detect whether the workpiece moves into the accommodating groove 182, so that the workpiece can be clamped by the subsequent mechanical arm for the next step.

The vibratory lifting assembly 19 vibrates in a vertical direction so as to be able to shake the workpiece off the roller track 12.

The air blowing assembly 20 includes an air guide duct 21 provided at the top of the loading tray assembly 10, and an air supply assembly communicating with the air guide duct. The air supply assembly is not shown in the drawings. The air guide pipe is arranged at the top of the feeding disc assembly. The air guide duct 21 is disposed at the top of the outer baffle 151 or the inner baffle 152. The outside of the air guide pipe 21 is sleeved with a mounting block 22, and a bolt passes through the mounting block 22 to fix the air guide pipe 21 on the top of the outer baffle 151 or the inner baffle 152. The inner baffle 152 and the outer baffle 151 may be preset with a plurality of bolt holes, so that any air guide pipe may be installed according to actual needs or installed at a responsive position to ensure the moving speed of the workpiece.

The angle adjusting device 30 includes a mounting bar 31 disposed along the roller rail 12, a height adjusting U-shaped block 32 disposed at both ends of the mounting bar 31, and a fixed rotating block 33. The vibration lift assembly is disposed 19 between the mounting bar 31 and the tray 11. The height-adjusting U-shaped block 32 and the fixed rotating block 33 are fixedly provided on the bottom surface, respectively. The fixed rotating block 33 is close to the discharge end of the roller track 12. The end of the mounting rod 31 is a movable end and can rotate around the fixed rotating block on a vertical plane. The tail end of the mounting rod 31 is clamped in the height-adjusting U-shaped block 32, two ends of the height-adjusting U-shaped block 32 are respectively provided with a vertical groove 34, and each vertical groove 34 is respectively provided with an adjusting bolt. The inclination angle of the roller rail 12 can be changed by fixing the mounting bar 31 at different positions in the height-adjusting U-shaped block 32.

One side of each roller track 12 is provided with a workpiece feeding sensor 121, and the workpiece feeding sensors 121 are infrared sensors and detect light rays perpendicular to the roller tracks 12. When the workpiece feeding sensor cannot detect the passing of the workpiece for a long time, the corresponding electric control device sends out an instruction to remind the staff to continue feeding.

Compared with the prior art, the air-blowing feeding assembly provided by the utility model has the advantages that the air-blowing assembly and the vibration lifting assembly are arranged, the vibration lifting assembly vibrates the workpiece in the vertical direction, and then the air-blowing assembly blows along the extending direction of the roller track, so that the vibrated workpiece is blown into the accommodating groove.

The above is only a preferred embodiment of the present utility model and is not intended to limit the scope of the present utility model, and any modifications, equivalent substitutions or improvements within the spirit of the present utility model are intended to be covered by the claims of the present utility model.

Claims (10)

1. An air-blown material loading subassembly, its characterized in that: the air-blowing feeding assembly comprises a feeding disc assembly which is horizontally arranged, a blowing assembly which is arranged at the top of the feeding disc assembly, and a vibration lifting assembly which is arranged at the bottom of the feeding disc assembly, wherein the feeding disc assembly comprises a disc body, at least one roller rail which is arranged at the top of the disc body, at least four supporting columns which are arranged at the bottom of the disc body, and a gap structure which is arranged between the disc body and each supporting column, the blowing assembly comprises an air outlet direction and an air guide pipe which is consistent with the direction of the roller rail, at least one air guide pipe is arranged at one side of each roller rail, the vibration lifting assembly vibrates along the vertical direction so as to shake a workpiece which is arranged at the top of the roller rail away from the roller rail, and the blowing assembly blows the workpiece along the direction of the roller rail so as to realize the movement of the workpiece.

2. The air-blown feed assembly of claim 1, wherein: every gap structure is in including setting up the U type buckle of charging tray subassembly bottom, the opening of U type buckle is down and open-ended two lateral walls are provided with the dog respectively, the side of support column is close to the position on support column top has seted up an annular groove, and the terminal cartridge of support column is in the U type buckle, so that the annular groove with the dog position corresponds.

3. The air-blown feed assembly of claim 2, wherein: the U-shaped buckles of the gap structure on each feeding disc assembly have at least two installation directions, and an included angle is formed between the same side surfaces of the U-shaped buckles, so that the feeding disc assemblies are limited to deviate from the top ends of the supporting columns due to horizontal displacement caused by vibration.

4. The air-blown feed assembly of claim 1, wherein: one end of the feeding disc assembly is provided with a workpiece accommodating table, the workpiece accommodating table comprises an accommodating seat, an accommodating groove corresponding to each roller rail, at least one roller arranged at the bottom of each accommodating groove, and a first sensor inserted at one side of each accommodating groove, and the accommodating grooves are communicated with the corresponding roller rails.

5. The air-blown feed assembly of claim 1, wherein: the top of material loading disc subassembly is provided with prevents that the work piece from roller bearing track top deviate from limit structure, limit structure includes two edges roller bearing track extending direction sets up and is located the outer baffle of material loading disc subassembly both sides, works as when the orbital quantity of roller bearing is two at least, limit structure is still including setting up the edge roller bearing track extending direction sets up and is located two adjacent interior baffles between the roller bearing track, outer baffle with interior baffle respectively with disk body parallel arrangement, outer baffle with the projection of interior baffle on the horizontal plane all falls adjacent in the roller bearing track.

6. The air-blown feed assembly of claim 1, wherein: the bottom of material loading disc subassembly is provided with and is used for controlling material loading disc subassembly inclination's angle adjustment device, the support column is scalable, angle adjustment device includes a root edge the installation pole that roller bearing track direction set up sets up respectively a altitude mixture control U-shaped piece at installation pole both ends, and a fixed rotating block, vibration lifting subassembly sets up the installation pole with between the disk body, altitude mixture control U-shaped piece with fixed rotating block is fixed respectively to be set up in the bottom surface, fixed rotating block is close to roller bearing orbital discharge end, the one end cartridge of installation pole is in the altitude mixture control U-shaped piece, vertical groove has been seted up respectively at the both ends of altitude mixture control U-shaped piece, every be provided with an adjusting bolt in the vertical groove respectively, in order selectively will the one end of installation pole is fixed at different altitudes.

7. The air-blown feed assembly of claim 1, wherein: the number of the roller tracks is 4.

8. The air-blown feed assembly of claim 5, wherein: the air guide pipe is arranged at the top of the inner baffle plate or the outer baffle plate on the adjacent side of the roller track, and the air guide pipe is detachably connected with the inner baffle plate and the outer baffle plate through bolts.

9. The air-blown feed assembly of claim 7, wherein: one side of each roller track is provided with a workpiece feeding sensor respectively, and the workpiece feeding sensors are infrared sensors and detect light rays perpendicular to the roller tracks.

10. The air-blown feed assembly of claim 1, wherein: the feeding end of the feeding disc assembly is provided with a feeding baffle plate, the feeding baffle plate is vertically arranged, a positioning hole for a workpiece to pass through is formed in the position of the feeding baffle plate corresponding to each roller rail, and the end face of the feeding baffle plate is provided with a feeding guide plate.