CN215852077U - Go into support case packer - Google Patents

Abstract

The utility model relates to the technical field of packaging equipment and discloses a box entering and packing machine. The tray loading device is arranged at one end of the first conveying mechanism and used for placing the tray on the first conveying mechanism, and the first conveying mechanism can convey the tray along the horizontal X direction; the second conveying mechanism can convey the workpieces along the horizontal Y direction and arrange the workpieces into workpiece groups; the first manipulator is used for grabbing and placing the workpiece group in a tray on the first conveying mechanism; the third conveying mechanism and the first conveying mechanism are arranged side by side and are used for conveying the outer box along the horizontal X direction; the second manipulator is used for placing the tray full of the workpiece group into the outer box on the third conveying mechanism. The supporting box filling machine is compact in overall structure, high in box filling efficiency and good in safety.

Description

Go into support case packer

Technical Field

The utility model relates to the technical field of packaging equipment, in particular to a box entering and packing machine.

Background

At present, in the industries of daily chemicals, medicines, foods and the like, a bottle/can is often required to be used for containing products, and the bottle/can needs to be further externally packaged in the transportation process so as to prevent the bottle/can from being abraded and collided. When the bottle/canned products are packaged, the bottles are required to be orderly stacked and placed into the support, and then the trays are sequentially placed into the outer box.

Therefore, a need exists for a box filling machine to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a supporting box filling machine which is compact in overall structure, high in box filling efficiency and good in safety.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a palletizing box filler comprising:

the tray feeding device is arranged at one end of the first conveying mechanism and used for placing the tray on the first conveying mechanism, and the first conveying mechanism can convey the tray along the horizontal X direction;

the second conveying mechanism is arranged on one side of the first conveying mechanism and can convey the workpieces along the horizontal Y direction and arrange the workpieces into workpiece groups;

the first mechanical arm is used for grabbing and placing the workpiece group in the tray on the first conveying mechanism;

the third conveying mechanism is arranged in parallel with the first conveying mechanism and is used for conveying the outer box along the horizontal X direction;

and the second manipulator is used for placing the tray filled with the workpiece group into the outer box on the third conveying mechanism.

Optionally, the first conveying mechanism comprises:

the first conveying assembly can bear and convey the tray along the horizontal X direction, a first station, a second station, a third station and a fourth station are sequentially arranged on the first conveying assembly along the conveying direction of the tray, the tray feeding device can place the tray on the first station, the second station is used for caching the tray, and the first manipulator can place the workpiece group in the tray on the third station;

a vision assembly for detecting the set of tools in the pallet at the fourth station.

Optionally, the first station, the second station and the third station are provided with:

a detection member for detecting the tray (100) at a corresponding station;

the first stop plate can selectively protrude out of the bearing plane of the first conveying assembly to stop the tray from moving or be positioned below the bearing plane of the first conveying assembly to avoid the tray from moving.

Optionally, the first conveying mechanism further comprises a press roller assembly arranged between the third station and the fourth station, and the tray loaded with the workpiece group can pass below the press roller assembly;

the press roll assembly includes:

the supporting component is arranged on the upper side of the first conveying component in a spanning mode;

the compression roller is rotatably supported on the downward side of the support assembly, the axis of the compression roller extends along the horizontal Y direction, and the distance between the compression roller and the bearing plane of the first conveying assembly is adjustable.

Optionally, the palletizing box filler further comprises an auxiliary conveying mechanism, and the auxiliary conveying mechanism comprises:

the second conveying assembly is arranged at one end, far away from the tray feeding device, of the first conveying assembly and can convey the tray along the horizontal X direction, a fifth station and a sixth station are sequentially arranged on the second conveying assembly along the conveying direction of the tray, and the second manipulator can grab the tray filled with the workpiece group from the fifth station.

Optionally, the second manipulator includes the horizontal migration subassembly, connects the lifting unit of horizontal migration subassembly's output and connects the first tongs subassembly of lifting unit's output, first tongs subassembly can snatch the tray, the horizontal migration subassembly can drive first tongs subassembly moves along the horizontal direction, lifting unit can drive first tongs subassembly moves along vertical Z to.

Optionally, the second conveying mechanism comprises:

the third conveying assembly is arranged on one side of the first conveying mechanism and can bear and drive the workpiece to move along the horizontal Y direction;

the limiting plate is arranged at one end, close to the first conveying mechanism, of the third conveying assembly;

and the grids are arranged on the upper side of one end, close to the limiting plate, of the third conveying assembly at intervals in parallel, and one workpiece can be accommodated between every two adjacent grids.

Optionally, second conveying mechanism still includes prevents stifled subassembly, prevent stifled subassembly setting and be in the grid is kept away from one side of limiting plate, prevent stifled subassembly and include:

the supporting frame is arranged on the upper side of the third conveying assembly in a spanning mode;

the shifting piece is connected with the supporting frame and can reciprocate relative to the supporting frame along the horizontal X direction.

Optionally, the first manipulator comprises:

a mechanical arm;

the second gripper assembly is connected with the conveying end of the mechanical arm, a plurality of grooves are formed in the second gripper assembly, an adsorption port is formed in each groove, and each adsorption port can correspondingly adsorb one workpiece in the same group of workpiece groups;

and the vacuum degree detection piece is arranged at the adsorption port and used for detecting the vacuum degree corresponding to the adsorption port.

Optionally, the tray feeding device comprises:

a bin for receiving the trays in a stacked arrangement;

the lifting mechanism can drive the tray to move up and down;

and the third mechanical arm can grab the uppermost layer of the tray in the stock bin and drive the tray to move along the horizontal X direction and the vertical Z direction.

The utility model has the beneficial effects that:

the in-tray box filler disclosed by the utility model has the advantages that the whole processes of stacking workpieces, assembling workpieces into a tray and boxing the workpieces do not need manual operation, so that the labor intensity is reduced, the production efficiency is improved, the workpieces are not easy to damage in the whole process, and the safety is good; in addition, the first conveying mechanism for conveying the tray and the third conveying mechanism for conveying the outer box are arranged side by side, and the first conveying mechanism of the second conveying mechanism for conveying the stacking workpieces is vertically arranged, so that all parts of the whole box filling machine for entering the tray are reasonably arranged, the whole structure is compact, and the arrangement position in a workshop can be flexibly selected.

Drawings

Fig. 1 is a schematic structural diagram of a palletizing box filler according to an embodiment of the present invention;

FIG. 2 is a top view of a palletizing and boxing machine in accordance with an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a first conveying mechanism provided in the embodiment of the present invention;

FIG. 4 is a top view of a second conveyor mechanism provided in accordance with an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a first robot according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of an auxiliary conveying mechanism provided in the embodiment of the present invention;

fig. 7 is a schematic structural diagram of a second robot provided in an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of a third conveying mechanism provided in the embodiment of the present invention;

fig. 9 is a schematic structural diagram of a tray feeding device according to an embodiment of the present invention.

In the figure:

100-a tray; 200-a workpiece; 300-outer case;

1-a tray feeding device; 11-a storage bin; 12-a lifting mechanism; 13-a third manipulator; 131-a traverse assembly; 132-a vertical shift assembly; 133-a third gripper assembly; 1331-a second gripper bracket; 1332-a second elastic suction claw;

2-a first conveying mechanism; 21-a first transport assembly; 22-a first station; 23-a second station; 24-a third station; 25-a fourth station; 26-a vision component; 27-a first stop plate; 28-a press roll assembly; 281-a support member; 282-a pressure roller;

3-a second conveying mechanism; 31-a third transport assembly; 32-limiting plate; 33-a grid; 34-an anti-blocking component; 341-a support frame; 342-a plectrum;

4-a first manipulator; 41-a mechanical arm; 42-a second gripper assembly; 421-groove;

5-a third conveying mechanism; 51-roller transport assembly; 52-first stop; 53-a second stop;

6-a second manipulator; 61-a horizontal movement assembly; 62-a lifting assembly; 63-a first gripper assembly; 631-a first suction jaw support; 632-a first elastic suction claw;

7-an auxiliary conveying mechanism; 71-a second conveyor assembly; 72-a fifth station; 73-a sixth station; 74-a second stop plate;

8-protective net.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting of the utility model. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, removably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present embodiment, the terms "upper", "lower", "right", etc. are used in an orientation or positional relationship based on that shown in the drawings only for convenience of description and simplicity of operation, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used only for descriptive purposes and are not intended to have a special meaning.

The present embodiment provides a palletizing box filler which can be used for packaging workpieces 200 such as bottles/canned products, bottle caps and the like. The X direction in fig. 1 indicates a horizontal X direction, i.e., a conveying direction of the tray 100, the Y direction indicates a horizontal Y direction, i.e., a conveying direction of the workpiece 200, the Z direction is a vertical direction, i.e., a vertical Z direction, and the X direction, the Y direction, and the Z direction are perpendicular to each other. In the present embodiment, the workpiece 200 is a bottled product, and the tray 100 is provided with a plurality of rows of slots, each slot is used for placing one workpiece 200, and each outer box 300 can be stacked into the multi-layer tray 100. The palletizing and boxing machine of the embodiment can arrange the independent and scattered workpieces 200 into workpiece groups arranged according to a certain rule, then assemble the products into the trays 100, and finally load the trays 100 filled with the workpiece groups into the outer box 300.

Specifically, as shown in fig. 1 and fig. 2, the palletizing and boxing machine comprises a pallet feeding device 1, a first conveying mechanism 2, a second conveying mechanism 3, a first manipulator 4, a third conveying mechanism 5 and a second manipulator 6, wherein, the tray feeding device 1 is arranged at one end of the first conveying mechanism 2 and is used for placing the tray 100 on the first conveying mechanism 2, the first conveying mechanism 2 can convey the tray 100 along the horizontal X direction, the second conveying mechanism 3 is arranged at one side of the first conveying mechanism 2, the second conveying mechanism 3 can convey the workpiece 200 along the horizontal Y direction, and the workpieces 200 are arranged into workpiece groups, the first manipulator 4 is used for grabbing the workpiece groups and placing the workpiece groups in the trays 100 on the first conveying mechanism 2, the third conveying mechanism 5 is used for conveying the outer boxes 300 along the preset direction, and the second manipulator 6 is used for placing the trays 100 filled with the workpiece groups in the outer boxes 300 on the third conveying mechanism 5.

The in-tray box filler of the embodiment has the advantages that the whole process of stacking the workpieces 200, assembling the workpieces into a tray and packing the tray 100 is realized without manual operation, so that the labor intensity is reduced, the production efficiency is improved, the workpieces 200 are not easy to damage in the whole process, and the safety is good; in addition, the first conveying mechanism 2 for conveying the tray 100 and the third conveying mechanism 5 for conveying the outer box 300 are arranged side by side, and the second conveying mechanism 3 for conveying the stacked workpieces 200 is arranged perpendicular to the first conveying mechanism 2, so that all parts of the whole box filling machine are reasonably arranged, the whole structure is compact, and the arrangement position in a workshop can be flexibly selected.

Preferably, as shown in fig. 1 and 2, the first conveying mechanism 2 and the third conveying mechanism 5 both extend along the horizontal direction X, the third conveying mechanism 5 is disposed on the right side of the first conveying mechanism 2 along the conveying direction of the pallet 100, the second conveying mechanism 3 is also disposed on the right side of the first conveying mechanism 2 along the conveying direction of the pallet 100, and the second conveying mechanism 3 is disposed over the third conveying mechanism 5 in a straddling manner, and one end of the second conveying mechanism 3 is butted against the first conveying mechanism 2, so that not only the first manipulator 4 can grasp the workpiece group on the second conveying mechanism 3, but also the overall structure of the box loader can be made more compact.

In this embodiment, as shown in the arrow direction in fig. 2, the tray 100 enters from the first end of the first conveying mechanism 2 and is conveyed along the horizontal X direction, the outer box 300 enters from the position of the third conveying mechanism 5 near the first end of the first conveying mechanism 2 and moves along the horizontal X direction, and the plurality of irregularly distributed workpieces 200 enter from the end of the third conveying mechanism 5 far from the first conveying mechanism 2 and are arranged in rows as workpiece groups arranged along the horizontal X direction when moving along the horizontal Y direction to the position near the first conveying mechanism 2.

Preferably, as shown in fig. 2 and 3, the first conveying mechanism 2 includes a first conveying assembly 21 and a vision assembly 26, the first conveying assembly 21 can carry the tray 100 and convey the tray 100 along the horizontal direction X, along the conveying direction of the tray 100, a first station 22, a second station 23, a third station 24 and a fourth station 25 are sequentially arranged on the first conveying assembly 21, the tray loading device 1 can place the tray 100 on the first station 22, the second station 23 is used for buffering the tray 100, the first robot 4 can correspondingly place the workpiece group in the tray 100 at the third station 24, and the vision assembly 26 is used for detecting the workpiece group in the tray 100 on the fourth station 25. It should be noted that the stations in this embodiment only represent relative positions, and the first conveying assembly 21 can drive the tray 100 to sequentially pass through the first station 22, the second station 23, the third station 24 and the fourth station 25 to realize the conveying of the tray 100.

The first manipulator 4 picks the workpiece groups from the second conveying mechanism 3 and correspondingly places the workpiece groups in the tray 100 located at the third station 24, and a plurality of workpiece groups can be placed in one tray 100, so that the time for the tray 100 to stay at the third station 24 may not match the time for the tray 100 to be placed to the first station 22, in this embodiment, the second station 23 is arranged between the first station 22 and the third station 24, and the time of the two steps can be coordinated, so that the beat for placing the tray 100 on the first conveying assembly 21 and the beat for placing the workpiece groups in the tray 100 are matched; the vision component 26 arranged at the fourth station 25 can photograph each passing tray 100 and confirm whether the tray 100 is full, thereby ensuring that each tray 100 filled into the outer box 300 is in a full-load state and ensuring the qualified rate of the workpiece 200 packing.

Specifically, in this embodiment, first conveyor assembly 21 is a belt conveyor assembly to guarantee the stationarity of tray 100 transportation process, in other embodiments, first conveyor assembly 21 also can be a chain conveyor assembly or a roller conveyor assembly, and belt conveyor assembly, chain conveyor assembly, roller conveyor assembly are prior art, and its specific structure is not repeated here. Further, the end of the second conveying mechanism 3 is located at one side of the third station 24, and the first manipulator 4 is located at the other side of the third station 24, so that the first manipulator 4 can conveniently realize grabbing and placing actions. The vision assembly 26 is a relatively mature part of the prior art, and the vision assembly 26 can be any one of the prior art without departing from the concept of the present invention.

Preferably, as shown in fig. 3, each of the first station 22, the second station 23 and the third station 24 is provided with a detecting member and a first stop plate 27, the detecting member is used for detecting the tray 100 at the corresponding station, and the first stop plate 27 can be selectively protruded out of the bearing plane of the first conveying assembly 21 to stop the movement of the tray 100 or positioned below the bearing plane of the first conveying assembly 21 to avoid the movement of the tray 100. The first conveying assembly 21 can simultaneously bear a plurality of trays 100, and the detection piece and the first stop plate 27 are arranged at each station, so that the movement of the tray 100 or the release of the tray 100 can be independently and flexibly selected and blocked at each station, and the smooth operation of the whole tray entering box filler is ensured. Preferably, a detecting member is also provided at the fourth station 25, and when the detecting member at the fourth station 25 detects that the tray 100 passes by, the detecting member communicates with the vision assembly 26, and the vision assembly 26 takes a picture to detect whether the workpiece 200 on the tray 100 is full.

Specifically, in this embodiment, as shown in fig. 3, the frame is provided with a first avoiding hole and a second avoiding hole at the first station 22, the second station 23 and the third station 24, the first avoiding hole is used for avoiding the movement of the first stopper plate 27, and the second avoiding hole is used for ensuring that the detection member can detect the tray 100 at the corresponding station. The fourth station 25 is provided with only the second avoidance hole. Alternatively, the detecting member may be a position sensor, a proximity switch, or the like, which is not limited herein.

Optionally, when the detecting member at the first station 22 detects that there is no tray 100 at the first station 22, the detecting member communicates with the tray feeding device 1, so that the tray feeding device 1 carries the tray 100 to the first station 22; when the detecting member at the third station 24 detects that the tray 100 is located at the third station 24, the first stop plate 27 at the third station 24 may protrude from the bearing surface of the first conveying assembly 21, so that the first robot 4 can load the workpiece group into the tray 100, and at this time, the first stop plate 27 at the second station 23 also protrudes from the bearing surface of the first conveying assembly 21 correspondingly, so as to stop the tray 100 from moving to the third station 24, and avoid collision between the trays 100. At this time, if the detecting member at the second station 23 detects that the tray 100 is located at the second station 23, the first stop plate 27 at the first station 22 protrudes from the carrying surface of the first conveying assembly 21, so as to prevent the tray 100 from moving to the second station 23; if the detecting member at the second station 23 detects that there is no tray 100 at the second station 23, the first stop plate 27 at the first station 22 is located below the carrying surface of the first conveyor assembly 21, so that the tray 100 at the first station 22 can move to the second station 23, so that the tray 100 at the second station 23 can move to the third station 24 quickly after the tray 100 at the third station 24 is full. The above is only one possible control method, and those skilled in the art can flexibly set the control method of the detecting member and the first stop plate 27 at each station, and will not be described herein again.

Preferably, as shown in fig. 3, the first conveying mechanism 2 further includes a pressing roller assembly 28, the pressing roller assembly 28 is disposed between the third station 24 and the fourth station 25, the tray 100 loaded with the workpiece group can pass through the lower portion of the pressing roller assembly 28, and when the workpiece 200 is not completely clamped in the clamping slot of the tray 100, the height of the tray is higher than a preset height, so that the workpiece 200 can be corrected by the pressing roller assembly 28 when passing through the lower portion of the pressing roller assembly 28, and the workpiece 200 can be accurately clamped in the corresponding clamping slot.

Specifically, as shown in fig. 3, the pressing roller assembly 28 includes a supporting assembly 281 and a pressing roller 282, the supporting assembly 281 is arranged on the upper side of the first conveying assembly 21 in a straddling manner, the pressing roller 282 is rotatably supported on the downward side of the supporting assembly 281, and the axis of the pressing roller 282 extends along the horizontal Y direction, so that the tray 100 loaded with the workpiece group passes below the pressing roller 282, and when the workpiece 200 is higher than the lowest point of the pressing roller 282, the pressing roller 282 can push the workpiece 200 into the corresponding slot during rolling without rigid collision with the workpiece 200, and the safety of the workpiece 200 can be ensured. Preferably, the distance between the pressing roller 282 and the bearing plane of the first conveying assembly 21 is adjustable, so that when the tray 100 is loaded with workpieces 200 of different heights, the pressing roller 282 can be adjusted to an appropriate height, and the application range of the pressing roller assembly 28 is increased. Specifically, as shown in fig. 3, the supporting assembly 281 includes a screw rod, a guide post and a cross beam, the guide post and the cross beam are parallel to the screw rod, the screw rod extends along the vertical Z direction and is rotatably connected with the cross beam, the pressing roller 282 is rotatably supported at the lower side of the cross beam, the guide post is in sliding fit with the frame, the screw rod is in threaded fit with the frame, and when the screw rod is rotated, the screw rod drives the cross beam and the guide post to move up and down together relative to the first conveying assembly 21, so as to adjust the height of the pressing roller 282. In other embodiments, the specific structure of the height adjustment of the pressing roller 282 is not limited.

Preferably, as shown in fig. 2 and 4, the second conveying mechanism 3 includes a third conveying assembly 31, a limiting plate 32 and a plurality of grills 33, wherein the third conveying assembly 31 is disposed on one side of the first conveying mechanism 2, the third conveying assembly 31 is capable of carrying the workpiece 200 and driving the workpiece 200 to approach the first conveying assembly 21 along the horizontal Y direction, the limiting plate 32 is disposed at one end of the third conveying assembly 31 close to the first conveying mechanism 2, the plurality of grills 33 are disposed at an upper side of one end of the third conveying assembly 31 close to the limiting plate 32 at parallel intervals, and one workpiece 200 can be accommodated between two adjacent grills 33. When a plurality of workpieces 200 arranged irregularly move to an end close to the first conveying assembly 21 along the third conveying assembly 31, under the guiding and limiting effects of the plurality of grids 33 and the limiting plates 32, the workpieces 200 are arranged into a plurality of rows arranged along the horizontal X direction, each row of workpieces 200 is a workpiece group, and the first manipulator 4 can grab a group of workpieces at one time, so as to improve the efficiency of loading the workpieces 200 into the tray.

Preferably, as shown in fig. 4, the second conveying mechanism 3 further includes an anti-blocking assembly 34, the anti-blocking assembly 34 is disposed on one side of the grating 33 away from the limiting plate 32, the anti-blocking assembly 34 includes a supporting frame 341 and a shifting piece 342, wherein the supporting frame 341 is disposed on the upper side of the third conveying assembly 31 in a straddling manner, the shifting piece 342 is connected with the supporting frame 341, the shifting piece 342 can reciprocate relative to the supporting frame 341 along the horizontal X direction, the workpiece 200 can be shifted in the reciprocating process of the shifting piece 342, and the workpiece 200 is prevented from being blocked. Specifically, in this embodiment, the supporting frame 341 includes a motor and a screw rod extending along the horizontal X direction, the shifting block 342 is fixed on a nut, the nut is in threaded fit with the screw rod, the motor can drive the screw rod to rotate forward or backward, so that the nut drives the shifting block 342 to reciprocate along the horizontal X direction, and in other embodiments, the structure for driving the shifting block 342 to reciprocate along the horizontal X direction is not limited thereto, and is not limited herein. Further, in this embodiment, the third conveying assembly 31 is a belt conveying assembly, so as to ensure the smoothness of the conveying process of the tray 100, and in other embodiments, the third conveying assembly 31 may also be a chain conveying assembly or a roller conveying assembly. Optionally, in this embodiment, each workpiece group has ten workpieces 200, and in other embodiments, the specific number of each workpiece group may be flexibly selected, which is not limited herein.

Preferably, as shown in fig. 2 and 5, the first robot arm 4 includes a robot arm 41 and a second gripper assembly 42, wherein the second gripper assembly 42 is connected to a conveying end of the robot arm 41, a plurality of grooves 421 are provided on the second gripper assembly 42, one suction port is provided in each groove 421, each suction port can correspondingly suck one workpiece 200 in the same workpiece group, and the second gripper assembly 42 can simultaneously suck a whole workpiece group, so that loading of the tray 100 is efficiently achieved, and the structure is simple and the workpieces 200 are not easily damaged. Preferably, the first manipulator 4 further includes a vacuum degree detection component, each suction port is provided with a vacuum degree detection component, the vacuum degree detection components can determine whether the workpiece 200 is sucked in the groove 421 by detecting the vacuum degree of the corresponding suction port, and if the second gripper assembly 42 detects that the workpiece 200 is not sucked in the groove 421, the workpiece assembly is no longer loaded into the tray 100, but is placed in other recycling positions, so that it is ensured that no empty position is left in the tray 100. Particularly, in this embodiment, communicate with same vacuum pump after a plurality of absorption mouths communicate, the synchronous control a plurality of absorption mouths of being convenient for, also can be that every absorption mouth independently communicates with the vacuum pump in other embodiments. Alternatively, the robot arm 41 may be a six-axis robot arm 41 of any of the prior art. Further, as shown in fig. 1 and 2, a protection net 8 is disposed around the first manipulator 4 to protect the first manipulator 4, and the net structure facilitates observation of the operation of the first manipulator 4.

Preferably, as shown in fig. 2 and fig. 6, the palletizing box filler further comprises an auxiliary conveying mechanism 7, the auxiliary conveying mechanism 7 comprises a second conveying assembly 71, wherein the second conveying assembly 71 is arranged at one end of the first conveying assembly 21 away from the tray loading device 1, and is capable of conveying the tray 100 along the horizontal X direction, along the conveying direction of the tray 100, a fifth station 72 and a sixth station 73 are sequentially arranged on the second conveying assembly 71, when the vision assembly 26 at the fourth station 25 detects that the tray 100 is full of the workpiece 200, indicating that the tray 100 is loaded successfully, the tray 100 is conveyed to the fifth station 72 by the second conveying assembly 71, and waits for the second robot 6 to convey the tray onto the third conveying mechanism 5; when the vision assembly 26 detects that the tray 100 is not full of the workpieces 200, the tray 100 is not loaded properly, and at this time, the tray 100 passes through the fifth station 72 and moves to the sixth station 73 to wait for recovery, so that the trays 100 finally loaded into the outer box 300 are all in a full-load state, and the qualified rate of boxing is guaranteed.

Preferably, as shown in fig. 6, a second stop plate 74 is disposed between the fifth station 72 and the sixth station 73, the second stop plate 74 may selectively protrude from the bearing plane of the second conveyor assembly 71 to stop the tray 100 from moving, or recede below the bearing plane of the second conveyor assembly 71 to recede the tray 100 from moving, and the second robot 6 may grasp the tray 100 full of the group of the robots from the fifth station 72 and place the tray in the outer box 300 on the third conveyor mechanism 5. When the vision assembly 26 detects that the tray 100 is loaded successfully, the second stop plate 74 moves to protrude from the upper surface of the second conveying assembly 71, so that the tray 100 stays at the fifth station 72, otherwise, the second stop plate 74 moves to the avoiding state, so that the tray 100 moves to the sixth station 73. Further, in this embodiment, the second conveying assembly 71 is a belt conveying assembly, so as to ensure the smoothness of the conveying process of the tray 100, and in other embodiments, the second conveying assembly 71 may also be a chain conveying assembly or a roller conveying assembly, which is not limited herein.

Preferably, as shown in fig. 2 and 7, the second robot 6 includes a horizontal moving assembly 61, a lifting assembly 62 and a first gripper assembly 63, wherein the horizontal moving assembly 61 is disposed on the frame, the lifting assembly 62 is connected to an output end of the horizontal moving assembly 61, the first gripper assembly 63 is connected to an output end of the lifting assembly 62, the horizontal moving assembly 61 can drive the first gripper assembly 63 to move in a horizontal X direction, and the lifting assembly 62 can drive the first gripper assembly 63 to move in a vertical Z direction, so that the pallet 100 filled with the workpiece group at the fifth station 72 can be transported into the outer box 300 of the third transport line, and a plurality of pallets 100 can be sequentially stacked in the outer box 300. In this embodiment, the first conveying assembly 21 for conveying the tray 100 and the third conveying assembly 31 for conveying the outer box 300 are both arranged along the horizontal direction X, the second conveying assembly 71 for conveying the workpiece 200 and the second manipulator 6 for carrying the tray 100 loaded with the workpiece 200 are both arranged along the horizontal direction Y, and the four parts of structures are matched, so that the whole structure of the tray-entering box filler is regular and compact.

Specifically, in this embodiment, as shown in fig. 7, the first gripper assembly 63 includes a first suction claw support 631 and a plurality of first elastic suction claws 632 disposed on the first suction claw support 631, the first elastic suction claws 632 flexibly contact with the tray 100 to prevent damage to mechanical components and the tray 100, and when the first elastic suction claws 632 suck the tray 100 and detect that the vacuum degree reaches a desired range, the lifting assembly 62 and the horizontal moving assembly 61 drive the first gripper assembly 63 to move so as to move the tray 100 to a proper position. Further, the horizontal moving assembly 61 can be a structure that a motor is matched with a screw-nut pair, the lifting assembly 62 is connected with a nut, and when the motor drives the screw rod to rotate, the nut drives the lifting assembly 62 to move along the horizontal X direction; the vertical lifting assembly 62 can also be a structure that a motor is matched with a screw-nut pair, and the first gripper assembly 63 is connected with a nut of the lifting assembly 62. The horizontal moving assembly 61 and the lifting assembly 62 may be any assembly or component capable of outputting linear motion in the prior art without departing from the inventive concept of the present application, and are not limited herein.

Preferably, as shown in fig. 2 and 8, the third conveying mechanism 5 includes a roller conveyor assembly 51 extending in the horizontal direction X, and after the outer box 300 is placed on the roller conveyor assembly 51, the outer box 300 is transported to a position corresponding to the fifth station 72, so that the first robot 4 can place the tray 100 into the outer box 300. Preferably, as shown in fig. 8, the roller conveyor assembly 51 is provided with a second stop member 53 and a first stop member 52 at intervals along the conveying direction of the outer box 300, and each of the first stop member 52 and the second stop member 53 can selectively protrude from the bearing surface of the roller conveyor assembly 51 to stop the movement of the outer box 300 or be located below the bearing surface of the roller conveyor assembly 51 to avoid the movement of the outer box 300. Specifically, the first stop member 52 is used for stopping the outer boxes 300 at the position corresponding to the fifth station 72, so that the position stability in the process of loading the tray 100 into the box is ensured, the second stop member 53 is arranged at the upstream position of the first stop member 52, and when the first stop member 52 stops one outer box 300 and the second manipulator 6 loads the tray 100 into the outer box 300, the second stop member 53 can stop the subsequent outer boxes 300 from continuing to move, so that the outer boxes 300 are prevented from being extruded and collided.

Preferably, as shown in fig. 9, the tray loading device 1 includes a bin 11, a lifting mechanism 12 and a third manipulator 13, wherein the bin 11 is disposed at one end of the first conveying mechanism 2 and is used for accommodating the trays 100 stacked in the stacking arrangement, the lifting mechanism 12 can drive the trays 100 to move up and down, and the third manipulator 13 can grab the uppermost tray 100 in the bin 11 and drive the tray 100 to move along the horizontal X direction and the vertical Z direction. The bin 11 can guide the tray 100 which moves up and down, so that the third manipulator 13 can accurately grab the tray 100 on the uppermost layer; after the third manipulator 13 grabs the uppermost tray 100, the third manipulator 13 drives the tray 100 to move upward along the vertical Z direction to take the tray 100 away from the bin 11, and then the third manipulator 13 drives the tray 100 to move along the horizontal X direction to make the tray 100 be located right above the first station 22, and then the third manipulator 13 drives the tray 100 to move downward to place the tray 100 at the first station 22. After the third robot arm 13 grasps the uppermost tray 100, the lifting mechanism 12 drives the remaining trays 100 to move upward together, so that the tray 100, which was originally positioned at the next upper level, is moved to the position of the original uppermost tray 100 for subsequent grasping by the third robot arm 13. By repeating the above process, the trays 100 stacked in the magazine 11 are sequentially transferred to the first station 22.

As shown in fig. 9, in this embodiment, the traverse assembly 131 is a structure in which a motor cooperates with a screw nut pair, the vertical moving assembly 132 is a linear cylinder, the vertical moving assembly 132 is connected to a nut, the motor drives the screw to rotate, the nut drives the vertical moving assembly 132 to move along the horizontal X direction, and a piston of the linear cylinder extends out or retracts to drive the third gripper assembly 133 to lift. Further, as shown in fig. 9, the third gripper assembly 133 includes a second suction claw support 1331 and a plurality of second elastic suction claws 1332 disposed on the second suction claw support 1331, the second elastic suction claws 1332 are in flexible contact with the tray 100 to prevent damage to the mechanical components and the tray 100, and when the second elastic suction claws 1332 suck the tray 100 and detect that the vacuum degree reaches a desired range, the traverse assembly 131 and the vertical movement assembly 132 drive the second gripper assembly 42 to move, so as to move the tray 100 to the first station 22.

Preferably, the lifting mechanism 12 is a scissor lift, and the scissor lift occupies a small space after being folded, so that more trays 100 can be contained in the bin 11. Further, an upper limit electric eye, an original point electric eye and a lower limit electric eye are sequentially arranged in the stock bin 11 from top to bottom, the upper limit electric eye and the lower limit electric eye respectively limit the highest position and the lowest position of the lifting platform to prevent mechanical collision damage, the original point electric eye can record and lock the initial height of the lifting mechanism 12 to be used as a reference for lifting the lifting mechanism 12, and an alarm can be given out when the tray 100 is used up. The upper limit electric eye, the origin electric eye and the lower limit electric eye can be position sensors or proximity switches and the like, and are not limited herein.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the utility model and are not to be construed as limitations of the embodiments of the present invention, but may be modified in various embodiments and applications by those skilled in the art according to the spirit of the present invention, and the content of the present description should not be construed as a limitation of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. The utility model provides a go into support case packer which characterized in that includes:

the tray feeding device (1) is arranged at one end of the first conveying mechanism (2) and used for placing the tray (100) on the first conveying mechanism (2), and the first conveying mechanism (2) can convey the tray (100) along the horizontal X direction;

the second conveying mechanism (3) is arranged on one side of the first conveying mechanism (2), the second conveying mechanism (3) can convey the workpieces (200) along the horizontal Y direction, and the workpieces (200) are arranged in a workpiece group in a stacking mode;

a first manipulator (4) for gripping and placing the workpiece group in the tray (100) on the first transport mechanism (2);

a third conveying mechanism (5) which is arranged in parallel with the first conveying mechanism (2) and is used for conveying the outer box (300) along the horizontal X direction;

and the second mechanical hand (6) is used for placing the tray (100) filled with the workpiece group into the outer box (300) on the third conveying mechanism (5).

2. A palletizing box filler as claimed in claim 1, wherein the first conveying mechanism (2) comprises:

the first conveying assembly (21) can carry and convey the tray (100) along the horizontal X direction, a first station (22), a second station (23), a third station (24) and a fourth station (25) are sequentially arranged on the first conveying assembly (21) along the conveying direction of the tray (100), the tray loading device (1) can place the tray (100) on the first station (22), the second station (23) is used for caching the tray (100), and the first manipulator (4) can place the workpiece group in the tray (100) located at the third station (24);

a vision assembly (26) for detecting the set of workpieces within the tray (100) at the fourth station (25).

3. A palletizing box filler as in claim 2, wherein at each of said first station (22), said second station (23) and said third station (24):

a detection member for detecting the tray (100) at a corresponding station;

a first stop plate (27) capable of selectively protruding from the bearing plane of the first conveying assembly (21) to block the tray (100) from moving or being positioned below the bearing plane of the first conveying assembly (21) to avoid the tray (100) from moving.

4. A palletizing box loader as claimed in claim 2, wherein said first conveying means (2) further comprises a roller assembly (28) arranged between said third station (24) and said fourth station (25), the tray (100) loaded with said set of tools being able to pass under said roller assembly (28);

the press roll assembly (28) comprises:

a support component (281) which is arranged on the upper side of the first conveying component (21) in a spanning mode;

the pressing roller (282) is rotatably supported on one side of the downward supporting assembly (281), the axis of the pressing roller (282) extends along the horizontal Y direction, and the distance between the pressing roller (282) and the bearing plane of the first conveying assembly (21) is adjustable.

5. A palletizing boxing machine as claimed in claim 2, further comprising an auxiliary conveying mechanism (7), wherein said auxiliary conveying mechanism (7) comprises:

the second conveying assembly (71) is arranged at one end, far away from the tray feeding device (1), of the first conveying assembly (21) and can convey the tray (100) along the horizontal X direction, a fifth station (72) and a sixth station (73) are sequentially arranged on the second conveying assembly (71) along the conveying direction of the tray (100), and the second mechanical hand (6) can grab the tray (100) filled with the workpiece group from the fifth station (72).

6. A palletizing and boxing machine as claimed in claim 5, wherein the second manipulator (6) comprises a horizontal moving assembly (61), a lifting assembly (62) connected to the output end of the horizontal moving assembly (61), and a first gripper assembly (63) connected to the output end of the lifting assembly (62), the first gripper assembly (63) can grip the pallet (100), the horizontal moving assembly (61) can drive the first gripper assembly (63) to move in the horizontal direction, and the lifting assembly (62) can drive the first gripper assembly (63) to move in the vertical Z direction.

7. A palletizing box loader as claimed in any one of claims 1 to 6, characterized in that said second conveying means (3) comprises:

the third conveying assembly (31) is arranged on one side of the first conveying mechanism (2), and the third conveying assembly (31) can bear and drive the workpiece (200) to move along the horizontal Y direction;

the limiting plate (32) is arranged at one end, close to the first conveying mechanism (2), of the third conveying assembly (31);

and a plurality of grids (33) are arranged on the upper side of one end, close to the limiting plate (32), of the third conveying assembly (31) at intervals in parallel, and one workpiece (200) can be accommodated between every two adjacent grids (33).

8. A palletizing box filler as claimed in claim 7, wherein said second conveying mechanism (3) further comprises an anti-blocking assembly (34), said anti-blocking assembly (34) being provided on a side of said grid (33) remote from said limit plate (32), said anti-blocking assembly (34) comprising:

a support frame (341) straddling the upper side of the third conveying component (31);

and a paddle (342) connected to the support frame (341), wherein the paddle (342) is capable of reciprocating relative to the support frame (341) in the horizontal X direction.

9. A palletizing box loader as in any one of claims 1 to 6, characterized in that said first manipulator (4) comprises:

a robot arm (41);

the second gripper assembly (42) is connected with the conveying end of the mechanical arm (41), a plurality of grooves (421) are formed in the second gripper assembly (42), one adsorption port is formed in each groove (421), and each adsorption port can correspondingly adsorb one workpiece (200) in the same group of workpieces;

and the vacuum degree detection piece is arranged at the adsorption port and used for detecting the vacuum degree corresponding to the adsorption port.

10. A palletizing box loader as in any one of claims 1 to 6, characterized in that said palletizing feed device (1) comprises:

a magazine (11) for accommodating the trays (100) in a stacked arrangement;

a lifting mechanism (12) capable of driving the tray (100) to move up and down;

and the third mechanical arm (13) can grab the tray (100) on the uppermost layer in the storage bin (11) and drives the tray (100) to move along the horizontal X direction and the vertical Z direction.

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