CN213621676U - Automatic bulk sorting and warehousing system - Google Patents

Abstract

An automatic bulk picking and warehousing system comprises a goods shelf, a stacker, a conveying mechanism and a compound robot; the goods shelf comprises a plurality of goods storage positions, each goods storage position is used for storing a turnover box, and the turnover box is used for storing goods; the stacker comprises a bidirectional telescopic fork and a picking robot, the bidirectional telescopic fork is used for conveying the turnover boxes in the storage positions onto the bidirectional telescopic fork and conveying the turnover boxes back into the storage positions, and the picking robot is used for scanning one or more goods in the turnover boxes, identifying the positions of the goods to be picked and picking the goods according to the identified positions; the conveying mechanism is used for conveying the goods grabbed by the picking robot to the compound robot; the composite robot is used for carrying the goods conveyed by the conveying mechanism to the goods taking area. The utility model discloses an automatic storage system is selected to parts can select specific goods fast, selects efficiently.

Description

Automatic bulk sorting and warehousing system

Technical Field

The utility model relates to a and warehouse system technical field, in particular to change bulk cargo and select warehouse system.

Background

With the rapid development of the e-commerce industry, more and more community-type micro warehouses which are built close to the physical distance of consumers are developed, and the warehouse system has the function of rapidly delivering and fulfilling the goods of the consumers. The biggest problem that influences storage delivery and fulfillment at present is that it is not high to select efficiency, especially during peak period, traditional manual picking has the problem that inefficiency, with high costs and the degree of difficulty is big.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides an automatic bulk cargo selects warehouse system can select specific goods fast, selects efficiently.

An automatic bulk picking and warehousing system comprises a goods shelf, a stacker, a conveying mechanism and a compound robot; the goods shelf comprises a plurality of goods storage positions, each goods storage position is used for storing a turnover box, and the turnover box is used for storing goods; the stacker comprises a bidirectional telescopic fork and a picking robot, the bidirectional telescopic fork is used for conveying the turnover boxes in the storage positions onto the bidirectional telescopic fork and conveying the turnover boxes back into the storage positions, and the picking robot is used for scanning one or more goods in the turnover boxes, identifying the positions of the goods to be picked and picking the goods according to the identified positions; the conveying mechanism is used for conveying the goods grabbed by the picking robot to the compound robot; the composite robot is used for carrying the goods conveyed by the conveying mechanism to the goods taking area.

The utility model discloses an in the embodiment, above-mentioned robot of selecting includes the multiaxis arm and connects the visual scanner on this multiaxis arm and selects the executor, and this multiaxis arm can order about this visual scanner and should select the executor and remove to this turnover case top, and this visual scanner can scan and the identification position to the goods in this turnover case, should select the executor and snatch this goods that corresponds according to the position of discernment.

The utility model discloses an in the embodiment, above-mentioned vision scanner is including making a video recording module and light filling ware, and this light filling ware is fixed in the camera lens below of this module of making a video recording, and around the circumference setting of this camera lens, this light filling ware is used for the light filling in to this turnover case.

The utility model discloses an in the embodiment, above-mentioned stacker still includes elevating system, and this elevating system includes mounting bracket, sliding seat and lift driver, and this sliding seat slidable ground is connected on this mounting bracket, and this two-way flexible fork and this select robot fixed connection on this sliding seat, and this lift driver fixed connection is on this mounting bracket, and this lift driver is used for ordering about this sliding seat and reciprocates along the direction of height of this mounting bracket.

In an embodiment of the present invention, the first temporary storage box is fixedly connected to the movable seat, the first temporary storage box is used for accommodating the goods captured by the sorting actuator, the first temporary storage box includes a first housing, a first partition frame and a plurality of first turnover drivers, a first cavity is formed in the first housing, the first cavity is vertically through, the first partition frame is fixedly connected to the first cavity, a plurality of first accommodating channels for accommodating the goods are formed between the first partition frame and the first housing, a first bottom plate for plugging the first accommodating channels is disposed at the bottom of the first accommodating channels, the first turnover drivers correspond to the first accommodating channels, the first turnover drivers are fixedly connected to the first housing, and the first turnover drivers can order the first bottom plate for plugging or opening the first accommodating channels.

The embodiment of the utility model provides an in, above-mentioned stacker still includes translation mechanism, and this translation mechanism includes translation base, horizontal guide rail and translation driver, and this horizontal guide rail sets up in one side of this goods shelves, and this horizontal guide rail extends to this transport mechanism, and this translation base slidable ground is connected on this horizontal guide rail, and the tip fixed connection of this mounting bracket is on this translation base, and this translation driver fixed connection is on this translation base, and this translation driver is used for ordering about this translation base and removes along the horizontal direction.

The embodiment of the utility model provides an in, above-mentioned warehouse system is selected to automatic bulk spare still includes goods temporary storage mechanism, and this goods temporary storage mechanism is fixed in this transport mechanism's top, and this goods temporary storage mechanism corresponds the setting with this stacker, moves through this translation mechanism when this stacker to when making this first temporary storage case be in this goods temporary storage mechanism's top, this first upset driver orders about this first bottom plate and opens this first holding passageway, and this goods drops to this goods temporary storage mechanism in this first holding passageway.

In an embodiment of the present invention, the cargo temporary storage mechanism includes a second temporary storage box for containing the cargo falling from the first temporary storage box, the second temporary storage box includes a second housing, a second partition frame and a plurality of second turnover drivers, the second housing has a second cavity penetrating from top to bottom, the second partition frame is fixedly connected in the second cavity, a plurality of second receiving channels for receiving the cargo are formed between the second partition frame and the second housing, a second bottom plate for blocking the second receiving channels is disposed at the bottom of the second receiving channels, the second turnover drivers are disposed corresponding to the second receiving channels, the second turnover drivers are fixedly connected to the second housing, the second turnover drivers can drive the second bottom plate to block or open the second receiving channels, when the second turnover drivers drive the second bottom plate to open the second receiving channels, the goods in the second accommodating channel fall onto the conveying mechanism.

The utility model discloses an in the embodiment, above-mentioned warehouse system is selected to automatic bulk still includes packing mechanism, and this packing mechanism is fixed in this transport mechanism's top, and this packing mechanism is used for packing this goods, and this compound robot can be with this goods transport that the packing is good to this district of getting goods.

The embodiment of the utility model provides an in, the aforesaid is got goods district and is equipped with a plurality of goods wares of getting that pile up the setting, should get the back that the goods cupboard is close to this transport mechanism and have into the goods mouth, should get the front that the goods cupboard was kept away from this transport mechanism and be provided with and get the goods mouth and correspond the cabinet door that sets up with this, one side of this cabinet door articulates in this gets the goods cupboard, the opposite side of this cabinet door passes through the hasp structure and should get the goods cupboard and be connected, this composite robot can with this goods that the packing is good from this income goods mouth transport to this get in the goods cupboard.

The utility model discloses an in the embodiment, above-mentioned goods shelves still include the replenishment position, and this compound robot can carry this turnover case to be deposited to this replenishment position, and this stacker can carry this turnover case to this stock position of this replenishment position.

The utility model discloses an automatic storage system is selected to bulk has begun automation when carrying the turnover case to two-way flexible fork and has selected the goods, reaches the purpose of selecting specific goods fast, selects efficiently, has solved whole packing box transport back manual work and has selected the low efficiency problem.

Drawings

Fig. 1 is a schematic top view of the automated bulk picking and warehousing system of the present invention.

Fig. 2 is a front view structure diagram of the shelf of the present invention.

Fig. 3 is a schematic view of a three-dimensional structure of the stacker of the present invention.

Fig. 4 is a schematic view of the stacker shown in fig. 3 in another direction.

Fig. 5 is a schematic perspective view of the bidirectional telescopic fork of the present invention.

Fig. 6 is an enlarged schematic structural view of the picking robot of the present invention.

Fig. 7 is a schematic perspective view of the movable seat and the first temporary storage box according to the present invention.

Fig. 8 is a partial structural schematic diagram of the transfer mechanism of the present invention.

Fig. 9 is a schematic structural diagram of the cargo temporary storage mechanism of the present invention.

Fig. 10 is a schematic top view of the hybrid robot of the present invention.

Detailed Description

The application provides an automated bulk picking and warehousing system.

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only partial embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In order to facilitate understanding of those skilled in the art, the present application provides a specific implementation process of the technical solution provided by the present application through the following embodiments.

Fig. 1 is a schematic top view of the automated bulk picking and storing system of the present invention, fig. 2 is a schematic front view of a shelf of the present invention, as shown in fig. 1 and fig. 2, the automated bulk picking and storing system includes a shelf 10, a stacker 20, a conveying mechanism 30 and a compound robot 40; the shelf 10 comprises a plurality of storage positions 11, each storage position 11 is used for storing a turnover box 13, and each turnover box 13 is used for storing goods; the stacker 20 comprises a bidirectional telescopic fork 21 and a picking robot 22, wherein the bidirectional telescopic fork 21 is used for conveying the turnover boxes 13 in the stock position 11 onto the bidirectional telescopic fork 21 and conveying the turnover boxes 13 back into the stock position 11, and the picking robot 22 is used for scanning one or more goods in the turnover boxes 13, identifying the positions of the goods to be picked and picking the goods according to the identified positions; the conveying mechanism 30 is used for conveying goods grabbed by the picking robot 22 to the compound robot 40; the compound robot 40 is configured to transport the goods transferred by the transfer mechanism 30 to the pickup area 701.

When the stacker 20 receives the goods taking signal, the stacker 20 moves to the stock position 11 corresponding to the shelf 10 according to the goods taking signal; first, the bidirectional telescopic fork 21 is carried out of the turnover box 13 from the stock position 11; then, the picking robot 22 scans one or more goods in the turnover box 13, identifies the positions of the goods to be grabbed, and grabs the goods according to the identified positions of the goods; then the turnover box 13 is transported back to the storage space 11 by the bidirectional telescopic fork 21; then the stacker 20 moves to the conveying mechanism 30 and places the goods on the conveying mechanism 30; the transfer mechanism 30 transfers the goods to the compound robot 40; finally, the composite robot 40 carries the goods transferred by the transfer mechanism 30 to the goods taking area 701.

Therefore, the utility model discloses an automatic bulk cargo is selected warehouse system begins to automize when carrying turnover case 13 to two-way flexible fork 21 on and selects the goods, reaches the purpose of selecting specific goods fast, selects efficiently, has solved whole packing box transport back manual work and has selected low efficiency problem.

Further, fig. 3 is the perspective structure schematic diagram of the stacker of the present invention, fig. 4 is the schematic diagram of the stacker shown in fig. 3 in another direction, fig. 5 is the perspective structure schematic diagram of the bidirectional telescopic fork of the present invention, as shown in fig. 3, fig. 4 and fig. 5, the bidirectional telescopic fork 21 includes a telescopic driver 211, a fork tooth seat 212, a middle sliding fork 213 and a top sliding fork 214, the telescopic driver 211 is fixedly connected to the fork tooth seat 212, the middle sliding fork 213 is slidably connected to the fork tooth seat 212, the top sliding fork 214 is slidably connected to the middle sliding fork 213, the telescopic driver 211 can drive the middle sliding fork 213 and the top sliding fork 214 to move telescopically to carry the turnover box 13. For the structure and function of the bi-directional telescopic fork 21, please refer to the prior art, which is not described herein.

Further, the picking robot 22 includes a multi-axis robot arm 221, and a visual scanner 222 and a picking actuator 223 connected to the multi-axis robot arm 221, the multi-axis robot arm 221 may drive the visual scanner 222 and the picking actuator 223 to move above the turnover box 13, the visual scanner 222 may scan the goods in the turnover box 13 and identify the position, and the picking actuator 223 grasps the corresponding goods according to the identified position. In this embodiment, the turnover box 13 has a receiving cavity 101 for receiving goods, the receiving cavity 101 contains a plurality of goods, the goods are sequentially placed at the bottom of the receiving cavity 101, and the information such as the codes, the shapes, the colors, and the logistics list of the goods are opened toward the receiving cavity 101, so that the visual scanner 222 can conveniently scan and identify the goods.

Further, fig. 6 is the utility model discloses a select enlarged structure schematic diagram of robot, as shown in fig. 3, fig. 4 and fig. 6, vision scanner 222 is including making a video recording module 2221 and light filling ware 2222, and light filling ware 2222 is fixed in the camera lens below of making a video recording module 2221, and around the circumference setting of camera lens, light filling ware 2222 is used for the light filling in to turnover case 13. In the present embodiment, the visual scanner 222 is configured to scan and recognize information of the goods, such as codes/shapes/colors/logistics lists, until the goods to be picked are recognized, and the picking actuator 223 picks the specific goods according to the scanning result.

Further, the camera module 2221 includes a lens (not shown), a voice coil motor (not shown), a base (not shown), a filter (not shown), a photosensitive chip (not shown), and a circuit board (not shown), wherein the lens is connected to the voice coil motor, the voice coil motor is fixedly connected to the base, the base is fixedly connected to the circuit board, the filter is fixedly connected to the base, the filter is disposed opposite to the lens, the photosensitive chip is electrically connected to the circuit board, and the photosensitive chip is disposed opposite to the filter.

Further, the light supplement 2222 is, for example, an LED lamp.

Further, as shown in fig. 3, 4 and 6, the vision scanner 222 further includes a fixing frame 2223, the camera module 2221 and the light compensator 2222 are fixedly connected to the fixing frame 2223, and the fixing frame 2223 is fixedly connected to the picking actuator 223.

Further, the picking actuator 223 includes a vacuum pump (not shown), a vacuum tube and a suction nozzle, the vacuum pump is fixedly connected to the multi-axis robot arm 221, one end of the vacuum tube is connected to the vacuum pump, the other end of the vacuum tube is connected to the suction nozzle, and when the vacuum pump pumps air, the suction nozzle can suck the goods to realize the grabbing action.

In another preferred embodiment, the selecting actuator 223 comprises an inflator, a connecting base, a flexible bag body and a hollow telescopic tube, wherein the connecting base is fixedly connected with a first joint and a second joint, the flexible bag body is connected to the connecting base, a chamber communicated with the first joint is arranged in the flexible bag body, the chamber is filled with fluid particles, the hollow telescopic tube is arranged in the chamber, the hollow telescopic tube is connected between the connecting base and the flexible bag body, and the second joint is communicated with the hollow telescopic tube; when positive pressure is applied to the flexible bag body and the hollow telescopic pipe, the flexible bag body gradually approaches to goods to be grabbed until the flexible bag body presses the goods; when negative pressure is applied to the flexible bag body and the hollow telescopic pipe, the flexible bag body coats the goods, and the mobile particles form a rigid state to realize grabbing action.

Further, the multi-axis robot arm 221 includes a fixing base 2211, a first axis driver (not shown), a second axis driver (not shown), a first speed reducer (not shown), a second speed reducer (not shown), a first movable arm 2212 and a second movable arm 2213, the first axis driver is fixedly connected in the fixing base 2211, the first speed reducer is connected to a driving end of the first axis driver, one end of the first movable arm 2212 is connected to the first speed reducer, the other end of the first movable arm 2212 is fixedly connected to the second axis driver, the second speed reducer is connected to a driving end of the second axis driver, one end of the second movable arm 2213 is connected to the second speed reducer, and the vision scanner 222 and the picking actuator 223 are connected to the second movable arm 2213. In the present embodiment, the one-axis driver and the two-axis driver are, for example, motors.

In another preferred embodiment, the multi-axis robot 221 is a six-axis robot, and the detailed structure is referred to above, which is not described herein again, but is not limited thereto.

Further, intelligent bulk picking device still includes elevating system 23, and elevating system 23 includes mounting bracket 231, sliding seat 232 and lift driver 233, and sliding seat 232 connects on mounting bracket 231 slidably, and two-way flexible fork 21 and picking robot 22 fixed connection are on sliding seat 232, and lift driver 233 fixed connection is on mounting bracket 231, and lift driver 233 is used for ordering about sliding seat 232 to reciprocate along the direction of height of mounting bracket 231.

Further, fig. 7 is a schematic perspective view of the movable seat and the first temporary storage box of the present invention, as shown in fig. 3, 4 and 7, the movable seat 232 is fixedly connected to a first temporary storage box 24, the first temporary storage box 24 is used for accommodating goods captured by the picking actuator 223, the first temporary storage box 24 includes a first housing 241, a first partition 242 and a plurality of first turning drivers 243, a first cavity penetrating up and down is formed in the first housing 241, the first partition 242 is fixedly connected in the first cavity, a plurality of first accommodating channels 102 for accommodating goods are formed between the first partition 242 and the first housing 241, a first bottom plate 244 for blocking the first accommodating channels 102 is disposed at the bottom of each first accommodating channel 102, each first turning driver 243 is disposed corresponding to each first accommodating channel 102, each first turning driver is fixedly connected to the first housing 241, and the first turning driver 243 can drive the first bottom plate 244 to block or open the first accommodating channel 102.

Further, the first casing 241 is rectangular, the first casing 241 includes a first side plate 2411, a second side plate 2412, a third side plate 2413 and a fourth side plate 2414, the first side plate 2411 and the second side plate 2412 are parallel and opposite to each other, the third side plate 2413 and the fourth side plate 2414 are parallel and opposite to each other, the first side plate 2411 and the second side plate 2412 are fixedly connected between the third side plate 2413 and the fourth side plate 2414, and the first side plate 2411, the second side plate 2412, the third side plate 2413 and the fourth side plate 2414 surround to form a first cavity.

Further, the first partition frame 242 includes at least one first main board and at least one first partition 2421, the first main board is perpendicularly cross-connected with the first partition 2421, two ends of the first main board are respectively fixedly connected to the first side board 2411 and the second side board 2412, and two ends of the first partition 2421 are respectively fixedly connected to the third side board 2413 and the fourth side board 2414. In the present embodiment, the first partition frame 242 only includes a first partition 2421, two ends of the first partition 2421 are respectively and fixedly connected to the third side plate 2413 and the fourth side plate 2414, and two first accommodating channels 102 are formed between the first partition frame 242 and the first housing 241, but not limited thereto.

Further, the movable seat 232 includes a sliding block 2321 and a bearing plate 2322, the sliding block 2321 is connected to the mounting frame 231 through a sliding chute and a sliding rail in a matching manner, one end of the bearing plate 2322 is fixedly connected to the sliding block 2321, the bidirectional telescopic fork 21, the picking robot 22 and the first temporary storage box 24 are fixedly connected to the bearing plate 2322, a picking through hole (not shown) is formed in the bearing plate 2322, the picking through hole penetrates through the bearing plate 2322, the picking through hole is arranged corresponding to each first accommodating channel 102, and when the first tilting driver 243 drives the first bottom plate 244 to open the first accommodating channel 102, the goods in the first accommodating channel 102 fall out of the picking through hole. In this embodiment, the loading plate 2322 is vertically connected to the outer wall of the sliding block 2321.

Further, the mounting frame 231 includes a column 2311, a driving wheel (not shown), a driven wheel (not shown) and a transmission belt 2312, the driving wheel is rotatably connected to the top of the column 2311, the driven wheel is rotatably connected to the bottom of the column 2311, the transmission belt 2312 is respectively connected to the driving wheel and the driven wheel, the sliding block 2321 is fixedly connected to the transmission belt 2312, the lifting driver 233 is fixedly connected to the top of the column 2311, a driving shaft of the lifting driver 233 is connected to the driving wheel, and the lifting driver 233 drives the movable seat 232 to move up and down through the transmission belt 2312. In this embodiment, the lifting driver 233 is a motor, and controls the motor to rotate forward and backward to move the movable base 232 up and down.

Further, the stacker 20 further includes a translation mechanism 25, the translation mechanism 25 includes a translation base 251, a horizontal guide 252 and a translation driver 253, the horizontal guide 252 is disposed at one side of the shelf 10, the horizontal guide 252 extends to the conveying mechanism 30, the translation base 251 is slidably connected to the horizontal guide 252, an end of the mounting frame 231 is fixedly connected to the translation base 251, the translation driver 253 is fixedly connected to the translation base 251, and the translation driver 253 is used for driving the translation base 251 to move along the horizontal direction. The stacker 20 is movable in a horizontal direction as a whole by the translation mechanism 25, for example, to a specific one or more storage spaces 11 of the shelf 10, and after sorting the goods, the stacker 20 is moved as a whole to the conveying mechanism 30 and the sorted goods are placed on the conveying mechanism 30. In this embodiment, the translation driver 253 is a motor.

Further, fig. 8 is a partial structure schematic diagram of the conveying mechanism of the present invention, as shown in fig. 1 and fig. 8, the conveying direction of the conveying mechanism 30 is perpendicular to the length direction of the horizontal guide rail 252, the conveying mechanism 30 includes a conveying frame 31, a conveying belt 32 and a conveying driver (not shown), both ends of the conveying frame 31 are provided with a first transmission shaft (not shown) and a second transmission shaft (not shown), the first transmission shaft and the second transmission shaft are rotatably connected to the conveying frame 31, the conveying belt 32 is respectively connected to the first transmission shaft and the second transmission shaft, the conveying driver is fixedly connected to the conveying frame 31, the conveying driver is connected to the first transmission shaft and the second transmission shaft through a belt, and the conveying driver orders about the first transmission shaft and the second transmission shaft to rotate to realize conveying goods.

Further, as shown in fig. 8, the conveying mechanism 30 further includes a first baffle 33, a second baffle 34, and a third baffle 35, the first baffle 33, the second baffle 34, and the third baffle 35 are disposed along the conveying direction, the first baffle 33 is parallel to and opposite to the second baffle 34, the third baffle 35 is disposed between the first baffle 33 and the second baffle 34, a first conveying path is formed between the first baffle 33 and the third baffle 35, a second conveying path is formed between the second baffle 34 and the third baffle 35, and the first conveying path and the second conveying path can convey the same or different goods, respectively.

Further, fig. 9 is the structural schematic diagram of cargo temporary storage mechanism of the utility model, as shown in fig. 1, fig. 8 and fig. 9, the warehouse system is selected to automatic bulk piece still includes cargo temporary storage mechanism 50, cargo temporary storage mechanism 50 is fixed in the top of transport mechanism 30, cargo temporary storage mechanism 50 corresponds the setting with stacker 20, every stacker 20 corresponds cargo temporary storage mechanism 50 promptly, when stacker 20 removes through translation mechanism 25, and make first temporary storage box 24 be in the top of cargo temporary storage mechanism 50, first upset driver 243 orders about first bottom plate 244 and opens first holding passageway 102, the goods drops to cargo temporary storage mechanism 50 in first holding passageway 102.

Further, as shown in fig. 9, the temporary storage mechanism 50 for goods includes a second temporary storage box 51, the second temporary storage box 51 is used for containing goods falling from the first temporary storage box 24, the second temporary storage box 51 includes a second housing 511, a second partition 512 and a plurality of second turnover drivers 513, the second housing 511 has a second cavity penetrating up and down, the second partition 512 is fixedly connected in the second cavity, a plurality of second accommodating channels 103 for accommodating goods are formed between the second partition 512 and the second housing 511, a second bottom plate 514 for blocking the second accommodating channels 103 is provided at the bottom of each second accommodating channel 103, each second turnover driver 513 is provided corresponding to each second accommodating channel 103, each second turnover driver 513 is fixedly connected to the second housing 511, the second turnover driver 513 can drive the second bottom plate 514 to block or open the second accommodating channels 103, when the second turnover driver 513 drives the second bottom plate 514 to open the second accommodating channels 103, the goods in the second accommodating passage 103 fall onto the transfer mechanism 30. In the embodiment, when the automated bulk picking and warehousing system is in a large quantity of goods, the second temporary storage box 51 can temporarily store a plurality of kinds of goods, so as to reduce the system pressure, and the second accommodating passage 103 is selectively opened, so that the goods can be distributed to the conveying mechanism 30 in batches.

Further, the temporary storage mechanism 50 further includes a support frame 52, the support frame 52 is fixedly connected to the conveying mechanism 30, and the second temporary storage box 51 is connected to the support frame 52. In this embodiment, the bottom of the supporting frame 52 is fixedly connected to the conveying frame 31, the second temporary storage box 51 is spaced from the upper portion and the lower portion of the conveying belt 32, and when the second flipping driver 513 drives the second bottom plate 514 to open the second accommodating passage 103, the goods in the second accommodating passage 103 fall onto the conveying belt 32.

Further, as shown in fig. 9, the cargo temporary storage mechanism 50 further includes a traverse driver (not shown) and a balance moving belt 54, the traverse driver is fixedly connected to the support frame 52, a traverse rotating shaft (not shown) is disposed on the support frame 52, one end of the balance moving belt 54 is connected to the traverse rotating shaft, the other end of the balance moving belt 54 is connected to the traverse driver, the second temporary storage box 51 is fixedly connected to the balance moving belt 54, and the traverse driver drives the second temporary storage box 51 to slide left and right on the support frame 52 through the balance moving belt 54.

Further, the second housing 511 is rectangular, the second housing 511 includes a fifth side plate 5111, a sixth side plate 5112, a seventh side plate 5113 and an eighth side plate 5114, the fifth side plate 5111 is parallel to and opposite to the sixth side plate 5112, the seventh side plate 5113 is parallel to and opposite to the eighth side plate 5114, the fifth side plate 5111 and the sixth side plate 5112 are fixedly connected between the seventh side plate 5113 and the eighth side plate 5114, and the fifth side plate 5111, the sixth side plate 5112, the seventh side plate 5113 and the eighth side plate 5114 surround to form a second cavity.

Further, the second partition frame 512 includes at least one second main plate 5121 and at least one second partition 5122, the second main plate 5121 and the second partition 5122 are perpendicularly cross-connected, two ends of the second main plate 5121 are respectively and fixedly connected to the fifth side plate 5111 and the sixth side plate 5112, and two ends of the second partition 5122 are respectively and fixedly connected to the seventh side plate 5113 and the eighth side plate 5114. In this embodiment, the second partition frame 512 only includes one second main plate 5121 and one second partition 5122, and four second receiving channels 103 are formed between the second partition frame 512 and the second housing 511, but not limited thereto.

Further, fig. 10 is the schematic view of the overhead structure of the composite robot of the present invention, as shown in fig. 10, the automatic bulk picking and storing system further includes a packing mechanism 60, the packing mechanism 60 is fixed above the conveying mechanism 30, the packing mechanism 60 is used for packing the goods, and the composite robot 40 can transport the packed goods to the goods taking area 701. For the structure of the packing mechanism 60 and the compound robot 40, reference is made to the prior art, and the description thereof is omitted.

Furthermore, the goods taking area 701 is provided with a plurality of goods taking containers 70 stacked, the back of each goods taking container 70 close to the conveying mechanism 30 is provided with a goods inlet, the front of each goods taking container 70 far away from the conveying mechanism 30 is provided with a goods taking port and a cabinet door arranged corresponding to the goods taking port, one side of the cabinet door is hinged to the goods taking container 70, the other side of the cabinet door is connected with the goods taking container 70 through a lock catch structure, and the composite robot 40 can carry the packaged goods into each goods taking container 70 from the goods inlet.

Furthermore, the goods taking area 701 is further provided with a freezer 80, the freezer 80 is arranged on one side of the goods taking cabinet 70, and the freezer 80 is used for refrigerating goods.

Further, the shelf 10 further includes a goods supply location 12, the compound robot 40 can convey the turnover boxes 13 to be stored to the goods supply location 12, and the stacker 20 can convey the turnover boxes 13 of the goods supply location 12 to the goods storage location 11.

Further, the automatic bulk picking and warehousing system further comprises a goods-entering counter 90, wherein goods to be stored are manually placed in the turnover boxes 13, the turnover boxes 13 are conveyed to the goods-entering counter 90, the composite robot 40 conveys the turnover boxes 13 to be stored to the goods-supplementing position 12, and finally the stacker 20 conveys the turnover boxes 13 of the goods-supplementing position 12 to the goods-storing position 11.

Further, the automated bulk picking and warehousing system further comprises a forklift 100, the forklift 100 is used for carrying large goods or containers, and the forklift 100 can directly carry the goods or the containers to the picking area 701.

The utility model discloses an automatic warehouse system is selected to bulk spare includes a plurality of goods shelves 10, a plurality of stacker 20, a plurality of goods temporary storage mechanism 50, and goods shelves 10, stacker 20 and goods temporary storage mechanism 50's quantity can be according to actual need free choice.

The utility model discloses still relate to an automatic bulk cargo selects storage method, this method utilizes foretell automatic bulk cargo to select storage system, and this method includes:

the stacker 20 receives the goods taking signal and moves to the stock position 11 corresponding to the goods shelf 10 according to the goods taking signal;

controlling the bidirectional telescopic fork 21 to carry the turnover box 13 from the stock position 11;

controlling the picking robot 22 to scan one or more goods in the turnover box 13, identifying the positions of the goods to be grabbed, and grabbing the goods according to the identified positions of the goods;

controlling the bidirectional telescopic fork 21 to convey the turnover box 13 back to the storage space 11;

controlling the stacker 20 to move to the conveying mechanism 30 and placing the goods on the conveying mechanism 30;

controlling the transfer mechanism 30 to transfer the goods to the compound robot 40;

the compound robot 40 is controlled to transport the goods transferred by the transfer mechanism 30 to the pickup area 701.

Specifically, the utility model discloses an automatic bulk cargo is selected storage method and is selected concrete step of goods includes:

step one, when the stacker 20 receives the goods taking signal, the stacker is moved to the stock position 11 storing the corresponding goods by the translation mechanism 25.

And step two, the lifting mechanism 23 drives the bidirectional telescopic fork 21 and the picking robot 22 to ascend or descend to a certain height until the bidirectional telescopic fork 21 corresponds to the turnover box 13.

In step three, the telescopic driver 211 drives the middle sliding fork 213 and the top sliding fork 214 to approach the turnover box 13 until the top sliding fork 214 is inserted into the bottom of the turnover box 13, and then the telescopic driver 211 drives the top sliding fork 214 to retract carrying the turnover box 13.

Step four, the multi-axis mechanical arm 221 drives the visual scanner 222 and the picking actuator 223 to move to the upper side of the turnover box 13, the visual scanner 222 can scan the goods in the turnover box 13 and identify the position, and the picking actuator 223 picks the corresponding goods according to the identified position.

Step five, the multi-axis robot arm 221 drives the visual scanner 222 and the picking actuator 223 to move above the first temporary storage box 24, and the picking actuator 223 deposits the goods in the first temporary storage box 24.

Step six, while picking the goods, the translation mechanism 25 moves to the conveying mechanism 30, the first flipping driver 243 drives the first bottom plate 244 to flip open the first accommodating passage 102, and the goods in the first accommodating passage 102 fall from the picking through holes to the conveying mechanism 30.

The utility model discloses an automatic storage method is selected to parts can be automatic when carrying turnover case 13 to two-way flexible fork 21 and select the goods, reaches the purpose of selecting specific goods fast, selects efficiently, has solved whole packing box transport back manual work and has selected the low efficiency problem.

Further, the automated bulk picking and warehousing method further comprises the following steps:

controlling the stacker 20 to sequentially grab a plurality of goods at the plurality of goods storage positions 11 and respectively place the plurality of goods in the plurality of first accommodating channels 102 of the first temporary storage box 24; that is, the stacker 20 can execute a plurality of picking tasks at the same time, improving the picking efficiency;

controlling the stacker 20 to move to the upper part of the second temporary storage box 51, and controlling to open each first accommodating channel 102 in sequence, so that the goods in each first accommodating channel 102 fall into a plurality of second accommodating channels 103 of the second temporary storage box 51;

the second temporary storage box 51 is fixed above the conveying mechanism 30, and controls to open each second accommodating passage 103, so that the goods in each second accommodating passage 103 fall on the conveying mechanism 30.

Further, the automated bulk picking and warehousing method further comprises the following steps:

controlling the packing mechanism 60 to pack the goods on the conveying mechanism 30;

and controlling the compound robot 40 to convey the packaged goods to the goods taking area 701.

Further, the automated bulk picking and warehousing method further comprises the following steps:

controlling the composite robot 40 to convey the turnover boxes 13 to be stored to the replenishment positions 12 of the shelves 10;

and controlling the stacker crane 20 to convey the turnover boxes 13 of the replenishment spaces 12 to the storage spaces 11.

The present application is not limited to the details of the above-described embodiments, and various simple modifications may be made to the technical solution of the present application within the technical idea of the present application, and these simple modifications are all within the protection scope of the present application. The various features described in the foregoing detailed description may be combined in any suitable manner without departing from the scope of the invention. In order to avoid unnecessary repetition, various possible combinations are not described separately in this application.

Claims (11)

1. An automatic bulk picking and warehousing system is characterized by comprising a goods shelf, a stacker, a conveying mechanism and a compound robot; the goods shelf comprises a plurality of storage positions, the storage positions are used for storing turnover boxes, and the turnover boxes are used for storing goods; the stacker comprises a bidirectional telescopic fork and a picking robot, wherein the bidirectional telescopic fork is used for conveying the turnover box in the storage position to the bidirectional telescopic fork and conveying the turnover box back to the storage position, and the picking robot is used for scanning one or more goods in the turnover box, identifying the position of the goods to be picked and picking the goods according to the identified position; the conveying mechanism is used for conveying the goods grabbed by the picking robot to the compound robot; the compound robot is used for transporting the goods conveyed by the conveying mechanism to the goods taking area.

2. The automated bulk picking warehousing system of claim 1, wherein the picking robot includes a multi-axis robotic arm that actuates the visual scanner and the picking actuator to move over the tote and a visual scanner and a picking actuator coupled to the multi-axis robotic arm that scans and identifies a location of the items within the tote, the picking actuator grasping the corresponding item based on the identified location.

3. The automated parts sorting and warehousing system of claim 2, wherein the vision scanner includes a camera module and a light supplement device, the light supplement device is fixed below a lens of the camera module and arranged around a circumference of the lens, and the light supplement device is used for supplementing light into the turnover box.

4. The automated bulk picking and warehousing system of claim 2, wherein the stacker further comprises a lifting mechanism including a mounting frame, a movable seat slidably coupled to the mounting frame, the bi-directional retractable fork and the picking robot fixedly coupled to the movable seat, and a lifting actuator fixedly coupled to the mounting frame for urging the movable seat to move up and down along a height of the mounting frame.

5. The automated bulk picking and warehousing system of claim 4 wherein a first staging box is fixedly attached to the movable seat, the first temporary storage box is used for containing the goods grabbed by the picking actuator and comprises a first shell, a first separation frame and a plurality of first turnover drivers, the first shell is provided with a first cavity which is communicated up and down, the first separation frame is fixedly connected in the first cavity, a plurality of first accommodating channels for accommodating the goods are formed between the first separating frame and the first shell, the bottom of the first containing channel is provided with a first bottom plate for plugging the first containing channel, the first turning driver is arranged corresponding to the first containing channel, the first turning driver is fixedly connected to the first shell and can drive the first bottom plate to close or open the first accommodating channel.

6. The automated bulk picking and warehousing system of claim 5, wherein the stacker further comprises a translation mechanism including a translation base, a horizontal rail disposed at a side of the rack, the horizontal rail extending to the transport mechanism, the translation base slidably coupled to the horizontal rail, an end of the mounting rack fixedly coupled to the translation base, and a translation driver fixedly coupled to the translation base for driving the translation base to move in a horizontal direction.

7. The automated bulk picking and warehousing system of claim 6, further comprising a temporary storage mechanism fixed above the conveying mechanism, wherein the temporary storage mechanism is disposed corresponding to the stacker, when the stacker moves through the translation mechanism and the first temporary storage box is located above the temporary storage mechanism, the first turning driver drives the first bottom plate to open the first receiving channel, and the goods in the first receiving channel drop onto the temporary storage mechanism.

8. The automated bulk picking and warehousing system of claim 7, wherein the cargo temporary storage mechanism includes a second temporary storage box for containing the cargo falling from the first temporary storage box, the second temporary storage box includes a second housing, a second partition frame and a plurality of second turning drivers, the second housing has a second cavity penetrating up and down, the second partition frame is fixedly connected to the second cavity, a plurality of second receiving channels for receiving the cargo are formed between the second partition frame and the second housing, a second bottom plate for blocking the second receiving channels is disposed at the bottom of the second receiving channels, the second turning drivers are disposed corresponding to the second receiving channels, the second turning drivers are fixedly connected to the second housing, the second turning drivers can drive the second bottom plate to block or open the second receiving channels, when the second turnover driver drives the second bottom plate to open the second accommodating channel, the goods in the second accommodating channel fall onto the conveying mechanism.

9. The automated bulk picking and warehousing system of claim 7, further comprising a packing mechanism secured above the transfer mechanism for packing the goods, the compound robot being capable of transporting the packed goods to the pickup area.

10. The automated bulk picking and warehousing system of claim 9, wherein the picking area is provided with a plurality of picking boxes stacked in a stacking manner, the picking boxes are provided with a goods inlet on the back side close to the conveying mechanism, the picking boxes are provided with a goods inlet on the front side far away from the conveying mechanism and a box door corresponding to the goods inlet, one side of the box door is hinged to the picking boxes, the other side of the box door is connected with the picking boxes through a locking structure, and the composite robot can convey the packaged goods from the goods inlet into the picking boxes.

11. The automated bulk picking and warehousing system of claim 1, wherein the racking further includes a restocking location to which the compound robot can transport the totes to be stored, the stacker can transport the totes at the restocking location to the stock location.

Images