CN217534097U - Warehousing system and sorting processing system - Google Patents

Abstract

The application provides a warehousing system and a sorting processing system. The warehousing system comprises a warehousing unit and a picking and transporting robot with a transfer device, the warehousing unit comprises a support, a platform track system arranged at the vertical top of the support and a plurality of storage columns arranged below the platform track system, and the storage columns are provided with a plurality of storage layers which are vertically arranged; the pick-and-place robot is configured to lower the transfer device to a position corresponding to a target storage tier of the target storage row on the side after moving to a target position of the platform rail system, and unload the storage object from the transfer device to the target storage tier or load the storage object from the target storage tier to the transfer device. The embodiment of the application can improve the system efficiency.

Description

Storage system and sorting processing system

Technical Field

The application relates to the technical field of intelligent logistics, in particular to a warehousing system and a sorting processing system.

Background

The sorting link is one of the key links in the warehousing operation. In a related technology, a robot moves on the ground, a motion area and a goods shelf area of the robot need to occupy the ground respectively, the occupied area is large, the motion area of the robot is limited by the goods shelf area, and when a plurality of robots work in the same area, the possibility of blockage is high, and the system efficiency is influenced.

SUMMERY OF THE UTILITY MODEL

The application aims at providing a warehousing system and a sorting processing system, and the system efficiency can be improved.

One aspect of the present application provides a warehousing system comprising at least one warehousing unit and at least one picking robot with a transfer device:

the storage unit comprises a support, a platform track system arranged at the vertical top of the support and a plurality of storage columns arranged below the platform track system, and the storage columns are provided with a plurality of storage layers arranged along the vertical direction;

the pick-and-place robot is configured to lower the transfer device to a position corresponding to a target storage tier of a target storage row on a side after moving to a target position of the platform rail system, and unload the storage object from the transfer device to the target storage tier or load the storage object from the target storage tier to the transfer device.

In one embodiment, the storage unit comprises shelf units arranged at intervals along a first direction, and the shelf units comprise at least two storage columns arranged along a second direction;

the target position corresponds to a spacing region between the shelf units spaced apart in the first direction.

In one embodiment, at least two of the storage columns of the shelving units form a unitary structure that is integrally movable relative to the rack; alternatively, the first and second electrodes may be,

at least two of the storage columns of the shelving units form a unitary structure with the rack.

In one embodiment, at least two of the storage columns of the shelving units form a unitary structure that is integrally movable relative to the rack;

the rack and the rack unit do not interfere with each other in the second direction, so that the rack unit can be moved out of the storage unit in its entirety in the second direction.

In one embodiment, the support and the platform rail system form a unitary structure;

the system comprises a plurality of the warehousing units, and a plurality of platform rail systems of the warehousing units are butted, so that the picking robot can move among the platform rail systems.

In one embodiment, the rack and/or the shelf unit is provided with a guide rail for guiding the transfer device to ascend and descend.

In one embodiment, the platform rail system is provided with a transfer port at the edge for the picking robot to load or unload the storage objects.

In one embodiment, the method further comprises:

an elevator including a ground operating platform and an elevating conveyor for transferring the storage objects between the ground operating platform and the pick-and-place robot at the transfer port; and/or the presence of a gas in the gas,

the ascending ladder is used for enabling an operator to ascend to the transfer port so as to throw the storage object to the picking and transporting robot at the transfer port; and/or the presence of a gas in the atmosphere,

and the automatic conveying line is matched with the height of the platform track system and is used for automatically throwing the storage objects to the pick-and-transport robot at the transfer port or providing the storage objects to an operator on the ascending ladder so that the operator can manually throw the storage objects to the pick-and-transport robot at the transfer port.

In one embodiment, the platform track system includes a first track group including a plurality of tracks extending in a first direction, respectively, and a second track group including a plurality of tracks extending in a second direction, respectively, the plurality of tracks of the first track group and the plurality of tracks of the second track group forming a plurality of grids, the plurality of grids forming a first grid area and a second grid area, the target storage column being located below the second grid area.

In one embodiment, the picking robot includes:

the movable base is used for driving the picking robot to move;

the transfer device comprises a transfer piece and a first driving device for driving the transfer piece;

and a lifting device including a lifting mechanism and a second driving device for driving the lifting mechanism, wherein the lifting mechanism is connected to the transfer device, and the second driving device is mounted on the movable base and is used for driving the lifting mechanism to lower the transfer device relative to the movable base to a position corresponding to the target storage layer, so that the transfer member is driven by the first driving device to unload the storage object from the transfer device to the target storage layer or load the storage object from the target storage layer to the transfer device.

In one embodiment, the first driving device is configured to drive the transfer member to perform a forward or reverse movement, so that the transfer member unloads the storage objects from the transfer device to one side when moving in the forward direction and unloads the storage objects from the transfer device to the other side when moving in the reverse direction; alternatively, the transfer member may be configured to load one of the storage objects on the transfer device when the transfer member moves in the forward direction and to load the other of the storage objects on the transfer device when the transfer member moves in the reverse direction.

In one embodiment, the movable base comprises a main body, a first driving wheel set capable of moving along the first direction in the same direction, and a second driving wheel set capable of moving along the second direction in the same direction;

the first driving wheel set and/or the second driving wheel set are arranged on the main body in a liftable mode.

In one embodiment, the picking and transporting robot further comprises an energy storage device for supplying power to the first driving device, and the energy storage device is connected with a battery mounted on the movable base.

In one embodiment, the energy storage device is mounted on the transfer device; the shifting device is provided with a first electric connection end connected with the energy storage device, and the movable base is provided with a second electric connection end connected with the battery;

the first and second electrical connection ends are configured to contact when the transfer device is in a retracted state, phase-separated in a descending movement of the transfer device.

In one embodiment, the main body of the movable base is an annular body penetrating through both ends in the lifting direction of the transfer device.

In one embodiment, the vertical dimension of the transfer device is smaller than the vertical dimension of the movable base;

the overall transverse external dimension of the transfer device is smaller than the transverse dimension of an inner hole formed by the inner annular wall of the annular body;

the transfer device is accommodated in the inner hole in a retracted state.

Another aspect of the application provides a sort processing system, comprising a warehousing system as described in any one of the above; the picking and transporting robot is configured to load sorted goods from a rotary package port, and unload the sorted goods to the target storage layer after the transfer device descends to a position corresponding to the target storage layer.

In an embodiment of the present application, the transfer robot is moved along a rail system on the top of the storage unit, so that the transfer robot lowers the transfer device to correspond to a target storage tier of a target storage column on the side of the target position, and transfers the storage object between the target storage tiers. The track system of the picking and transporting robot on the top of the storage unit moves, so that the picking and transporting robot can be prevented or reduced from occupying the ground area of the storage unit, a ground working area is reserved for other equipment or operators, and the system efficiency is improved; on the other hand, the transfer device is moved to the side of the target storage row, so that the transfer device can transfer the goods between any storage layer of the target storage row without being influenced by the goods of other storage layers, and therefore, the goods taking and transporting range of the robot is flexible. On the other hand, as the platform track system at the top of the storage unit is not provided with the goods shelf, the movement space of the picking and transporting robot in the platform track system is larger, and the degree of freedom of movement is also larger, the occurrence of blockage can be reduced, and the system efficiency is improved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The foregoing and other objects, features and advantages of the application will be apparent from the following more particular descriptions of exemplary embodiments of the application, as illustrated in the accompanying drawings wherein like reference numbers generally represent like parts throughout the exemplary embodiments of the application.

FIG. 1 illustrates a warehousing system according to an embodiment of the present application;

FIG. 2 illustrates a warehousing system according to another embodiment of the present application;

FIG. 3 illustrates a portion of the warehouse system of FIG. 2 from another perspective;

FIG. 4 is a floor plan of a stocker unit according to an embodiment of the present application;

FIG. 5 is a block diagram of a pick-and-place robot according to an embodiment of the present application;

FIG. 6 illustrates a pick-and-place robot according to an embodiment of the present application;

FIG. 7 shows a left side view of the pick-and-place robot of FIG. 6;

FIG. 8 shows a right side view of the pick-and-place robot of FIG. 6;

fig. 9 is a view showing a state in which the transfer mechanism of the transfer robot of fig. 6 is lowered;

fig. 10 is a view showing a state where the transfer device of the transfer robot in fig. 6 is lowered from another angle;

fig. 11 shows a cross-sectional view of the take-out robot of fig. 6;

fig. 12 shows a schematic diagram of the bidirectional transfer of the pick-and-place robot of fig. 6;

fig. 13 shows a management device control unit of an embodiment of the present application;

fig. 14 illustrates a transfer robot control unit according to an embodiment of the present application.

Reference numerals:

a storage unit 200; a bracket 210; a guide rail 212; a storage column 220; a first storage column 220A; a second storage column 220B; a cargo box 222; a shelf unit 230; a shelf body 232; a column 234; a layer rod 236; a platform rail system 240; a first track set 242; a second track set 244; a grid 246; a first grid area 252; a second grid area 254; a transfer port 256; the pick-and-place robot 300; a movable base 310; a main body 312; an inner annular wall 312a; a step 312b; an inner bore 313; a first set of drive wheels 314; a second set of drive wheels 316; an inner housing space 318; a battery 320; a transfer device 330; a roller bracket 332; a first driving device 333; a drive roller 334; a driven roller 336; a transfer member 337; a belt 338; a baffle 339; guide/guide block 340; an energy storage device 342; a first electrical connection terminal 344; a second electrical connection terminal 346; a lifting device 350; an elevating mechanism 351; a lift cord 352; a second drive unit 353; a control unit 360; a processor 362; a memory 364; an elevator 400; a ground console 402; operators 502, 504; a management device 600; a processor 610; and a memory 620.

Detailed Description

Preferred embodiments of the present application will be described in more detail below with reference to the accompanying drawings. While the preferred embodiments of the present application are shown in the drawings, it should be understood that the present application may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this application and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

It should be understood that although the terms "first," "second," "third," etc. may be used herein to describe various information, these information should not be limited to these terms. These terms are only used to distinguish one type of information from another. For example, first information may also be referred to as second information, and similarly, second information may also be referred to as first information, without departing from the scope of the present application. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In the description of the present application, it is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be considered limiting of the present application.

Unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and encompass, for example, being fixedly connected, releasably 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 meaning of the above terms in the present application can be understood by those of ordinary skill in the art as the case may be.

The technical solutions of the embodiments of the present application are described in detail below with reference to the accompanying drawings.

Referring to fig. 1 to 3, the warehousing system of the embodiment includes at least one warehousing unit 200 and at least one picking robot 300.

The stocker unit 200 includes racks 210, a platform track system 240 provided at the vertical top of the racks 210, and a plurality of storage columns 220 provided below the platform track system 240, the storage columns 220 having a plurality of storage levels arranged in a vertical direction. The platform rail system 240 includes a first rail group 242 and a second rail group 244, the first rail group 242 including a plurality of rails extending in a first direction, respectively, the second rail group 244 including a plurality of rails extending in a second direction, respectively, the plurality of rails of the first rail group 242 and the plurality of rails of the second rail group 244 forming a plurality of grids 246, the plurality of grids 246 forming a first grid area 252 and a second grid area 254, and the plurality of storage columns 220 arranged below the second grid area 254.

The transfer robot 300 has a transfer device, and the transfer robot 300 is configured to move along the platform rail system 240, control the transfer device to descend vertically from the target grid 246 in the first grid area 252 to a position corresponding to a target storage tier of the target storage tier in the plurality of storage tiers 220 below the second grid area 254, and transfer storage objects between the target storage tiers on the sides.

In some embodiments, the plurality of tracks of the first track set 242 are spaced apart in parallel along the second direction and the plurality of tracks of the second track set 244 are spaced apart in parallel along the first direction. In fig. 1, X shows a first direction, Y shows a second direction, and Z shows a vertical direction. In this application, the vertical direction is also the lifting direction of the transfer device of the transfer robot 300. Referring to fig. 1-3, in one implementation, the first direction X is perpendicular to the second direction Y, and the vertical direction Z is perpendicular to a transverse plane defined by the first direction X and the second direction Y. Each grid 246 of the platform rail system 240 is formed by two adjacent rails of the first rail group 242 and two adjacent rails of the second rail group 244, and a plurality of grids 246 formed by a plurality of rails of the first rail group 242 and a plurality of rails of the second rail group 244 are arranged in a matrix. It is to be understood that the present application is not limited thereto.

FIG. 4 illustrates a floor plan of a warehouse unit 200 in one implementation. In the figure, marks a to G denote lift tables, and marks 1_L to 20\ l and 1_R to 20 \\ r denote the storage columns 220. Of the multiple grids formed by the platform rail system 240, the grid corresponding to each storage column 220 is the grid in the second grid region 254, and the other grids without the storage column 220 below form the first grid region 252, that is, in fig. 4, the grids marked 1 to 20 and the other grids without the marks are the grids in the first grid region 252.

In some embodiments, the storage unit 200 includes shelf units 230 spaced along a first direction, the shelf units 230 including at least two storage columns 220 arranged along a second direction; the spacing region between the shelf units 230 spaced apart in the first direction corresponds to the first grid region 252 of the platform rail system 240.

In some embodiments, at least two storage columns 220 of shelf units 230 form a unitary structure that is integrally movable with respect to the racks 210 of the warehouse units 200. That is, the shelf unit 230 is provided independently of the bracket 210 and is movable with respect to the bracket 210. For example, as shown in the example of fig. 2, the shelving unit 230 includes shelving bodies 232 and a plurality of containers 222 arranged in an array, the shelving bodies 232 including a plurality of uprights 234, and sets of tier rods 236 connected between the uprights 234, each set of tier rods 236 forming a shelf tier, the containers 222 supported between each set of tier rods 236. The shelf bodies 232 are provided independently of the rack 210 and are movable with the containers 222 relative to the rack 210. It will be appreciated that in other embodiments, each set of deck rods 236 may be replaced with a deck upon which the cargo box 222 is placed. The cargo box 222 may be an order box, a tote, or the like.

For example, in fig. 4, each 5 storage columns 220 arranged in the second direction Y are configured as one shelf unit 230, that is, 1_L to 5_L, 6_L to 10_, 11 _Lto 15_, 16 _Lto 10 _Lare respectively configured as shelf units, and 1_R to 5_R, 6_R to 10_r, 11 _rto 15_r, and 16 _rto 10 _rare respectively configured as shelf units. It is understood that the number of columns of the shelf unit 230 and the number of layers of each column may be configured according to actual needs.

In some embodiments, at least two storage columns 220 of shelf units 230 are formed as a unitary structure with the racks 210 of the warehouse units 200. For example, the shelf bodies 232 of the shelf units 230 may be formed directly from the racks 210 of the warehouse units 200.

In some embodiments, at least two storage columns 220 of shelf units 230 form a unitary structure that is integrally movable with respect to the racks 210 of the storage units 200, and the racks 210 and shelf units 230 do not interfere with each other in the second direction, such that the shelf units 230 can be integrally moved out of the storage units 200 in the second direction.

In some embodiments, the rack 210 of the stocker unit 200 and the platform rail system 240 form a unitary structure, and the platform rail system 240 is fixedly mounted to the rack 210, such that the stocker unit 200 forms an independent module.

In some embodiments, the stocker system includes a plurality of stocker units 200, and the platform rail systems 240 of the plurality of stocker units 200 are interfaced such that the picking robot 300 can move between the platform rail systems 240. In some implementations, the platform track systems 240 of adjacent stocker units 200 may be fixedly connected, for example, by connectors, to ensure a stable and smooth interface between the platform track systems 240.

In some embodiments, the stocker unit 200 is provided with a guide rail 212 for guiding the transfer device of the transfer robot 300 to be lifted. The guide rail 212 may be provided on the bracket 210 and/or on the shelf body 232.

In some embodiments, the platform rail system 240 is provided with a transfer opening 256 at an edge thereof for the transfer robot 300 to load or unload the storage objects. In one particular implementation as shown in fig. 4, the transfer ports 256 are located at an edge grid 246 of the platform track system 240, and the pick-up robot 300 may move to the edge grid 246 to load or unload stored objects.

In some embodiments, the warehousing system further includes an elevator 400, the elevator 400 includes a ground console 402, and a lifting and lowering conveyor (not shown), the ground console 402 is used for an operator 502 on the ground to pick up or put in objects, such as sorted goods, which are transported to the ground console 402 by the operator 502 and then put in the ground console 402. The elevating conveyor is used to transfer the storage objects between the floor console 402 and the pick-and-place robot 300 at the transfer port 256.

As shown in fig. 2, in one embodiment, the ground console 402 is a semi-automatic console, for example, including a conveyor belt, which can convey the storage objects placed on the conveyor belt by the operator 502 to the lifting conveyor, and the lifting conveyor lifts the storage objects to the top of the stocker unit 200 and then drops the storage objects to the pick-and-place robot 300 at the transfer port 256 at the edge of the platform rail system 240. It will be appreciated that the stocker system may be configured with a plurality of elevators 400 and a plurality of the transfer robots 300 to improve efficiency.

In other embodiments, the warehousing system further includes a step ladder for an operator to step up to the transfer port 256 at the edge of the platform rail system 240 to manually release the stored objects to the pick-and-place robot 300. The dropped storage object may be, for example, sorted goods that are delivered to the top of the storage unit and are to be sorted by an operator.

In some embodiments, the warehousing system is configured with an automated conveyor line matching the height of the platform track system 240, which may be used to automatically deposit storage objects to the picking robot 300 at the transfer port 256 or to transport storage objects to an operator on an ascending ladder for the operator to manually deposit storage objects to the picking robot 300 at the transfer port 256. The automatic conveying line may convey the goods to be sorted to an operator, for example, and the operator puts the sorted goods sorted by the goods to be sorted into the picking robot 300.

Fig. 5 shows a block diagram of a picking robot 300 according to an embodiment of the present application. Referring to fig. 5, the picking robot 300 includes:

a movable base 310 for driving the transfer robot 300 to move on the support surface, for example, driving the transfer robot 300 to move along the platform rail system 240;

a transfer device 330 including a transfer member 337 and a first driving device 333 for driving the transfer member 337;

the lifting device 350 includes a lifting mechanism 351 and a second driving device 353 for driving the lifting mechanism 351, wherein the lifting mechanism 351 is connected with the transferring device 330, and the second driving device 353 is mounted on the movable base 310 and is used for driving the lifting mechanism 351 to lower the transferring device 330 to a position corresponding to the target storage layer relative to the movable base 310, so that the transferring member 337 is driven by the first driving device 333 to transfer the storage object to the target storage layer.

In some embodiments, the transfer robot further includes a control unit 360 for controlling the operation of the first and second driving devices 333 and 353 and controlling the movement of the movable base 310.

Referring to fig. 6, in some embodiments, the movable base 310 includes a main body 312, a first driving wheel set 314 capable of moving in a first direction, and a second driving wheel set 316 capable of moving in a second direction, and at least one of the first driving wheel set 314 and the second driving wheel set 316 is liftably mounted on the main body 312 to move the movable base 310 in the first direction or the second direction by alternately contacting the moving support surface.

In one embodiment, the main body 312 of the movable base 310 is an annular body, and penetrates through both ends along the lifting direction of the transfer device 330. The toroid has an inner annular wall, an outer annular wall, a top wall and a bottom wall that together define an interior receiving space 318 (as shown in fig. 11), the interior receiving space 318 may be used, for example, for a communications module, a power module, etc. of the Rong Zhiqu mobile robot 300. The body 312 is shown as a generally square ring. It will be appreciated that the present application is not limited thereto, and for example, the body may also be a rectangular, or oval ring, or the like. By providing the main body of the movable base as an annular body, the storage object can be loaded or unloaded from above the transfer robot 300 when the transfer device 330 is in the retracted state.

The first driving wheel set 314 and the second driving wheel set 316 are disposed at the bottom of the main body 312. The driving wheels of the first driving wheel set 314 are disposed at the bottom of the main body 312 along the first moving direction of the movable base 310, and are driven by one or more driving motors disposed in the internal accommodating space 318; the driving wheels of the second driving wheel set 316 are disposed at the bottom of the base along the second moving direction of the movable base 310, and are driven by one or more driving motors disposed in the internal receiving space 318. The first movement direction and the second movement direction may be perpendicular to each other, but the present application is not limited thereto. The first driving wheel set 314 is shown to include 4 driving wheels, each set of two driving wheels is disposed on one parallel side of the square body 312, and the second driving wheel set 316 includes 4 driving wheels, each set of two driving wheels is disposed on the other parallel side of the square body 312. It will be appreciated that in other embodiments, the number of drive wheels on each side of the square body 312 may be configured to be, for example, 1, or more than 2.

In some embodiments, the drive wheels of the first and second drive wheel sets 314, 316 are elevationally mounted to the body 312 to contact or move away from the moving support surface. The driving wheel is lifted in the same direction as the transfer device 330. Fig. 7 illustrates a state in which the driving wheels of the first driving wheel set 314 are in contact with the motion support surface and the driving wheels of the second driving wheel set 316 are spaced from the motion support surface, in which the first driving wheel set 314 may move the movable base 310 in the first motion direction in a forward or reverse direction, and fig. 8 illustrates a state in which the driving wheels of the second driving wheel set 316 are in contact with the motion support surface and the driving wheels of the first driving wheel set 314 are spaced from the motion support surface, in which the second driving wheel set 316 may move the movable base 310 in the second motion direction in a forward or reverse direction. It is understood that the driving motor and the lifting mechanism of the first and second driving wheel sets 316 can be disposed in the inner receiving space 318 of the main body 312.

Thus, by controlling the first driving wheel set 314 and the second driving wheel set 316 to alternately contact the moving support surface, the movable base 310 can be moved in different directions. The transfer robot 300 may move in the first direction X or in the second direction Y by controlling the first and second driving wheel sets 314 and 316 to alternately contact the rails of the first rail set 242 and the rails of the second rail set 244 while operating under the guidance of the platform rail system 240 on the top of the stocker unit 200.

In other embodiments, one of the first driving wheel set 314 and the second driving wheel set 316 is liftably mounted on the main body 312, for example, each driving wheel of the first driving wheel set 314 is liftably mounted on the main body 312, when each driving wheel of the first driving wheel set 314 is lowered to a position lower than each driving wheel of the second driving wheel set 316, each driving wheel of the first driving wheel set 314 contacts with the motion supporting surface, each driving wheel of the second driving wheel set 316 leaves the motion supporting surface, and at this time, the first driving wheel set 314 can move the movable base 310 in the first motion direction in the forward direction or the reverse direction; when the driving wheels of the first driving wheel set 314 are lifted to a position higher than the driving wheels of the second driving wheel set 316, the driving wheels of the first driving wheel set 314 leave the motion support surface, and the driving wheels of the second driving wheel set 316 contact the motion support surface, at this time, the second driving wheel set 316 can make the movable base 310 move forward or backward along the second motion direction. It is understood that, alternatively, each driving wheel of the second driving wheel set 316 may be elevatably mounted on the main body 312, and the first driving wheel set 314 and the second driving wheel set 316 are alternatively contacted with the moving support surface by controlling the elevation of the second driving wheel set 316.

In some embodiments, the first and second drive wheel sets 314, 316 effect a switch from tracks in the first track set 242 to tracks in the second track set 244 by way of differential rotation.

In some embodiments, the transfer device 330 includes a base, a transfer member, a first driving device, and a rolling support member driven by the first driving device, the rolling support member is supported by the base, and the transfer member and the rolling support member form a belt transmission connection.

Referring to fig. 9 to 12, in one embodiment, the transferring device 330 is a belt 338 transferring device 330, which includes a roller frame 332, a driving roller 334 and a driven roller 336 rotatably supported on the roller frame 332, and a belt 338 mounted on the driving roller 334 and the driven roller 336. The roller holder 332, which serves as a base of the transfer device 330, includes a pair of substantially parallel support rods. The driving roller 334 and the driven roller 336 are supported between the pair of support bars, the driving roller 334, and the driven roller 336 cause the transfer device 330 to have a shape substantially conforming to the main body 312; the first driving device 333 includes, for example, a drum motor, a stator of which is provided inside the driving drum 334, and the driving drum 334 serves as a rotor of the drum motor. When the drum motor is energized, the driving roller 334 rotates, and the belt 338 moves under rolling support of the driving roller 334 and the driven roller 336, so that the storage objects can be unloaded from the belt 338 to a target storage layer, or loaded onto the belt 338. It is understood that in other implementations, the first driving device 333 may be another type of motor, for example, may be disposed outside the driving roller 334, and a transmission mechanism, such as a reduction gear train, may be disposed between the first driving device 333 and the driving roller 334.

In some embodiments, a pair of baffles 339 are disposed at the top ends of the pair of support rods 332, and the baffles 339 extend along the moving direction of the belt and are used for limiting the objects to be stored, so as to prevent the objects to be stored from falling off the belt, and at the same time, the objects to be stored are not affected to be loaded or unloaded.

In some embodiments, the lift device 350 is a cord lift device that includes a lift cord 352 and a second drive device 353. The second driving means 353 may include a driving motor, such as a rotating motor, mounted to the main body 312 of the movable base 310, and provided in the inner receiving space 318 of the main body 312. The transfer device 330 is suspended at one end of the lifting rope 352, and the other end of the lifting rope 352 is directly or indirectly connected to the output end of the second driving device 353. When the second driving device 353 outputs the rotation in the first direction, the lifting rope 352 is wound to raise the transfer device 330; when the second driving device 353 outputs the rotation in the second direction, the lifting rope 352 is deployed to lower the transfer device 330. By controlling the output rotation amount of the second driving device 353, the degree of winding or unwinding of the lift rope 352 can be controlled, and the distance of ascending or descending of the transfer device 330 can be controlled. It is understood that the lift cord 352 may be a cable, chain, belt, or the like.

As shown in fig. 9 and 10, in one specific implementation, the rope lifting device 350 includes four lifting ropes 352 disposed at four top corners of the main body 312, a pair of support rods 332 of the transfer device 330 are respectively hung at two ends of one end of the four lifting ropes 352, and the other end of each lifting rope 352 is directly or indirectly connected to an output end of the corresponding second driving device 353; by synchronously winding or unwinding the four lifting ropes 352, the transfer device 330 can be raised or lowered smoothly.

Further, referring to fig. 11, the vertical dimension of the transfer device 330 is smaller than the vertical dimension of the main body 312, and the overall dimension of the transfer device 330 in the transverse direction is smaller than the transverse dimension of the inner hole 313 formed by the inner annular wall 312a of the main body 312, so that the transfer device 330 is not interfered with the main body 312 during the lifting process, and when the lifting device 350 is in the fully retracted state (in the above embodiment, the lifting rope 352 is in the fully wound state), the transfer device 330 is in the retracted state, the transfer device 330 is accommodated in the inner hole of the main body 312, and the picking robot 300 is in a flat shape. In this manner, the pick-and-place robot 300 is made more compact in structure and more stable when moving on the platform rail system 240.

In some embodiments, the transfer device 330 is provided with a guide 340 for sliding contact with an external guide rail to guide the lifting of the lifting device 350, so as to stabilize the transfer device 330 during the lifting process.

In the embodiment shown in the figure, the base of the transfer device 330 is provided with a guide block 340, and the guide block 340 slides along the guide rail 212 of the rack 210 of the storage unit 200 during the lifting process of the transfer device 330, so as to limit the lifting track of the transfer device 330. It is understood that the guide blocks 340 may be provided at some of the corners or all of the four corners of the transfer device 330.

In some embodiments, the main body 312 of the movable base 310 is provided with a battery 320 (as shown in fig. 5), for example, disposed in the inner accommodating space 318, and can be used to supply power to the control unit 360, the driving motors and the lifting mechanisms of the first driving wheel set 314 and the second driving wheel set 316, and the second driving device 353. The transfer device 330 is provided with an energy storage device 342 (shown in fig. 5) for supplying power to the first driving device 333. The energy storage device 342 may be a battery, a capacitor, or the like, and may be disposed within the drive roller 334, or within the substrate, for example. It is understood that in other embodiments, the energy storage device may not be provided in the picking robot, and the first driving device is powered by the battery.

In some embodiments, the battery 320 of the movable base 310 charges the energy storage device 342 of the transfer device 330. Further, the picking robot 300 is configured to electrically disconnect the energy storage device 342 from the battery 320 when the transfer device 330 is lowered, and electrically connect the energy storage device 342 to the battery 320 when the transfer device 330 is in the retracted state. Thus, when the transfer device 330 is in the retracted state, the battery 320 charges the energy storage device 342, and when the transfer device 330 descends to the target position, the energy storage device 342 supplies power to the first driving device 333, so that the transfer member 337 is driven by the first driving device 333 to unload the storage object from the transfer device 330 or load the storage object onto the transfer device 330.

As shown in fig. 9 to 11, in one specific implementation, the transfer device 330 is provided with a first electrical connection end 344 connected to the energy storage device 342, the movable base is provided with a second electrical connection end 346 matched with the first electrical connection end 344, and the second electrical connection end 346 is connected to the battery 320. When the transfer device 330 is in the retracted state, the first electrical connection end 344 and the second electrical connection end 346 are in contact with each other to electrically connect the energy storage device 342 and the battery 320, and when the transfer device 330 moves downward, the first electrical connection end 344 and the second electrical connection end 346 are separated from each other to electrically disconnect the energy storage device 342 and the battery 320. In the figure, the first electrical connection end 344 is an electrical connection contact, and the second electrical connection end 346 is an electrical connection contact. It will be appreciated that, alternatively, the first electrical connection end 344 is an electrical connection contact pad and the second electrical connection end 346 is an electrical connection contact; alternatively, the first electrical connection end 344 and the second electrical connection end 346 may form other types of electrical connection structures, such as a plug-in type. The energy storage device 342 may be a super capacitor configured to provide the required amount of power for transferring the transferring device 330 once after charging.

In some embodiments, the vertical top end of the main body 312 of the movable base 310 is provided with an inwardly extending step 312b. The inner wall of the step 312b may be used to limit the stored objects, preventing the stored objects from falling out of the picking and transporting robot 300; the bottom wall of the step 312b can be used to limit the movement of the transfer device 330 in the ascending direction.

In the specific implementation shown in fig. 9 to 11, the second electrical connection terminal 346 is disposed on the bottom wall of the step 312b, the first electrical connection terminal 344 is disposed on the top surface of the base body of the transfer device 330 facing the bottom wall of the step 312b, and when the transfer device 330 is in the retracted state, the first electrical connection terminal 344 and the second electrical connection terminal 346 are connected in contact with each other in the ascending and descending direction of the transfer device 330.

In some embodiments, the transfer device is an inverting transfer device including a base, an inverting table, and a first driving device for driving the inverting table. The first driving device is mounted on the base body. After the lifting device lowers the transfer device to the position corresponding to the target storage layer, the first driving device drives the overturning plate to turn on the side, so that the storage objects in the overturning plate fall to the target storage layer under the action of self gravity. It will be appreciated that a transmission mechanism, such as a reduction gear or the like, may be provided between the first drive means and the flipping disk.

In some embodiments, the transfer device is a fork transfer device comprising a base, a fork, and a first drive device for driving the fork. The first driving device is mounted on the base body. After the lifting device lowers the transfer device to a position corresponding to the target storage layer, the first driving device drives the fork to translate, so that the fork transversely pushes the storage object to the target storage layer, or the first driving device drives the fork to translate to the target storage layer and then reversely move, so that the fork pulls the storage object of the target storage layer to the transfer device.

In some embodiments, the transfer device is a roller transfer device.

Alternatively, in some embodiments, the lift mechanism 351 includes a scissor mechanism. One end of the shearing fork mechanism is arranged on the movable base, the other end of the shearing fork mechanism is arranged on the transfer device, and the shearing fork mechanism stretches under the driving of the second driving device, so that the transfer device can descend or ascend. The second driving means may be a driving motor but is not limited thereto.

Alternatively, in some embodiments, the lift mechanism 351 includes a multi-stage telescoping mechanism. In one specific implementation, the multistage telescoping mechanism comprises at least two telescopic arms which are sequentially connected in a sliding manner, and the at least two telescopic arms do nested telescopic motion relative to the movable base under the driving of the second driving device. Alternatively, in some embodiments, the first driving device is configured to drive the transfer member to perform a forward or reverse movement such that the transfer member unloads the stored objects from the transfer device to one side when moving in the forward direction and unloads the stored objects from the transfer device to the other side when moving in the reverse direction; alternatively, the transfer unit is configured to load one of the storage objects on the transfer unit when the transfer unit moves in the forward direction and to load the other storage object on the transfer unit when the transfer unit moves in the reverse direction.

Referring to fig. 12, in an embodiment, the first grid area 252 is located between two adjacent second grid areas 254, one of the two adjacent second grid areas 254 is provided with a first storage row 220A, and the other one of the two adjacent second grid areas 254 is provided with a second storage row 220B; the first driving device 333 of the picking robot 300 is configured to drive the transfer member (shown as a belt 338) to perform forward or reverse bidirectional movement so that the transfer member 337 unloads the storage objects from the transfer device 330 to the target storage tier of the first storage column 220A when moving in the forward direction and unloads the storage objects from the transfer device 330 to the target storage tier of the second storage column 220B when moving in the reverse direction; alternatively, the transfer member 337 is moved in the forward direction to load the storage object of the target storage tier in the first storage rank 220A to the transfer device 330, and moved in the reverse direction to load the storage object of the target storage tier in the second storage rank 220B to the transfer device 330.

An embodiment of the present application further provides a warehousing method, such as but not limited to the management device or the picking robot described above, including:

and controlling the picking and transporting robot with the transfer device to move to the target position along the rail system at the top of the storage unit so as to control the picking and transporting robot to lower the transfer device to a position corresponding to the target storage layer of the target storage column at the side of the target position, and transferring the storage object between the target storage layer and the target storage layer.

It will be appreciated that when the above method is applied to a management apparatus, the management apparatus sends a scheduling command to the picking robot, and the picking robot moves along the rail system to a target position in response to the scheduling command. The management equipment can select a carrying robot meeting the requirement from the plurality of carrying robots for scheduling according to a preset strategy. It will be appreciated that the management device may comprise one or more management terminals, and/or one or more management servers. The scheduling instruction transmitted by the management apparatus to the pick-up robot is not limited to a single instruction, and may be a combination of a plurality of instructions.

It can be understood that when the method is applied to the picking robot, the picking robot receives the dispatching command sent by the management device and moves to the target position along the rail system in response to the dispatching command.

The warehousing method of the application can be applied to a sorting link, for example. The warehousing method of another embodiment of the application comprises the following steps:

and SA10, controlling the picking and transporting robot with the transfer device to obtain the sorted goods at a transfer port arranged at the edge of the rail system at the top of the storage unit.

In some embodiments, the objects to be sorted are transported to a predetermined packing position at the top of the stocker unit, so that the sorted goods are sorted out from the objects to be sorted and dropped to the pick-up robot at the transfer port.

In some embodiments, the objects to be sorted are conveyed to a predetermined packing location at a floor console of the elevator, and the elevator conveyor controls the elevator to convey the sorted goods sorted from the objects to be sorted from the floor console to the transfer port. The predetermined bag-in-place at the ground operating floor may be on the ground operating floor or may be a location beside the ground operating floor.

And SA20, obtaining the position information to which the sorted goods are delivered, wherein the position information comprises the information of the target storage column and the target storage layer.

And SA30, controlling the picking robot to move to a target position adjacent to the target storage column along the rail system.

SA40, controlling the transfer robot to lower the transfer device to a position corresponding to a target storage tier of the target storage column on the side of the target position.

In some embodiments, the picking robot may determine a descending stroke distance of the transfer device according to the target storage layer information, and control the lifting device for lifting the transfer device according to the descending stroke distance.

In some embodiments, the picking robot may detect whether the target storage layer is reached in real time during the descending process, for example, a preset mark corresponding to each storage layer provided on a shelf or a rack may be detected during the descending process, or a preset mark on a container of each storage layer may be detected until a preset mark corresponding to the target storage layer is detected, and it is determined that the target descending position is reached.

SA50, controlling the transfer device to unload the sorted goods to the target storage layer, for example, unloading the containers loaded with the sorted goods to the target storage layer, or unloading the sorted goods into the containers at the target storage layer.

The above embodiments are further described below in connection with several specific application scenarios.

In one application, a plurality of orders can be integrated into an aggregate list, the types and/or the quantities of the goods required by the aggregate list are counted to obtain corresponding goods to be sorted, and then the goods required by each order are sorted from the goods to be sorted into corresponding order boxes. Correspondingly, the warehousing method of another embodiment of the application comprises the following steps:

SB10, counting the type and/or quantity of the required goods according to a plurality of orders.

And SB20, conveying the corresponding objects to be sorted to a preset packing position according to the types and/or data of the required goods, so that the sorted goods are sorted out from the objects to be sorted and are thrown to the picking robot at the packing transferring port.

And SB30, obtaining a target storage column and a target storage layer corresponding to the target order of the goods needing to be sorted in the plurality of orders.

SB40, controlling the picking robot to move to the target position adjacent to the target storage column along the rail system.

SB50, the transfer robot is controlled to lower the transfer device to a position corresponding to the target bank of the target bank on the side of the target position.

And SB60, controlling the transfer device to unload the order boxes containing the sorted goods to the target storage layer or unloading the sorted goods to the order boxes at the target storage layer.

In another application, single SKU items may be sorted into multiple order bins. Correspondingly, the warehousing method of another embodiment of the application comprises the following steps:

and SC10, the objects to be sorted containing a plurality of the same SKU commodities are conveyed to a predetermined packing position, so that the SKU commodities are sorted out of the objects to be sorted and are thrown to a picking robot at a package transferring port.

And the SC20 obtains the information of the target storage column and the target storage layer corresponding to the target order of the SKU commodity in the plurality of orders.

And the SC30 controls the picking robot to move to a target position adjacent to the target storage column along the rail system.

And SC40, controlling the picking and transporting robot to lower the transfer device to a position corresponding to the target storage layer of the target storage column at the side of the target position.

And the SC50 controls the transfer device to unload the SKU commodities to the order boxes at the target storage layer.

In another application, various miscellaneous items can be sorted according to the target of one SKU item, or a plurality of same SKU items, or one item. Correspondingly, the warehousing method of another embodiment of the application comprises the following steps:

SD10, the objects to be sorted containing various goods are conveyed to a preset bag supplying position, so that the sorted goods are sorted out from the objects to be sorted and are thrown to a picking robot at a bag transferring opening.

And SD20, obtaining a target storage column and a target storage layer corresponding to the sorted objects. The sorted goods may be sorted goods or a sort bin containing sorted goods, and the sorted goods may be, for example, a SKU good.

And SD30, controlling the picking robot to move to a target position adjacent to the target storage column along the rail system.

And SD40, controlling the picking and transporting robot to lower the transfer device to a position corresponding to a target storage layer of a target storage column on the side of the target position.

And SD50, controlling the transfer device to unload the sorted objects to the target storage layer or the target storage layer.

For example, the sorted object is a SKU item, and the transfer device unloads the SKU item to the target storage tier, which is only used for storing the SKU item.

For another example, the sorted object is a SKU commodity, and the transfer device unloads the SKU commodity into a target sorting bin of the target storage layer, where the target sorting bin is used for placing the same kind of goods or the same SKU commodity.

For another example, the sorted objects are sorting boxes containing sorted goods, and the transfer device unloads the sorting boxes to the target storage layer.

In some embodiments, the track system includes a first track group extending along a first direction and a second track group extending along a second direction, the first track group and the second track group together form a plurality of grids at a top of the warehousing unit, the plurality of grids form a first grid area and a second grid area, a plurality of storage columns are distributed below the second grid area, and the storage columns have a plurality of storage tiers.

In some embodiments, before controlling the transfer robot with the transfer device to move along the rail system on the top of the storage unit to the target position of the rail system, the method further includes:

determining a target storage column corresponding to the storage object; and

determining a target grid adjacent to the target storage column in the first grid area according to prestored map data of the track system and corresponding data of grids in the plurality of storage columns and the second grid area, wherein the target grid is a target position of the picking and transporting robot moving along the track system;

the map data of the track system includes distribution data of a plurality of grids, distribution data of a first track group and a second track group, distribution data of a first grid area, and distribution data of a second grid area.

In some embodiments, controlling a transfer robot having a transfer device to move along a rail system on top of a stocker unit to a target location of the rail system includes:

determining a motion path of the picking robot on the track system according to a target grid adjacent to the target storage column in the first grid area, distribution data of the first track group and the second track group and the current position of the picking robot; and the number of the first and second groups,

and controlling the moving robot to move to the target grid according to the movement path.

In some embodiments, the warehousing method further comprises: and controlling the pick-up and delivery robot to load or unload the storage objects at a bale transfer port arranged at the edge of the track system. The storage objects are loaded or unloaded at the top of the warehousing unit by controlling the picking robot, so that the picking robot only moves in the top track system of the warehousing unit, the turnover rate of the picking robot can be improved, and the stock or goods picking efficiency is improved.

In some embodiments, the warehousing method further comprises: and controlling the picking and transporting robot to load or unload the storage objects from the upper part of the picking and transporting robot at the bag transferring port arranged at the edge of the track system. For example, when the transfer robot is configured as shown in fig. 6 to 10, the transfer mechanism of the transfer robot 300 is retracted into the annular body of the movable base at the ladle opening 256, and the storage object can be loaded into or unloaded from the transfer device from the upper end opening of the annular body.

In some embodiments, the warehousing method further comprises: the storage objects are transferred between the picking robot at the transfer port and a ground operating platform or an automatic conveying line.

In some embodiments, the warehousing method further comprises: judging whether each goods position in the goods shelf finishes the loading or unloading of the corresponding storage object, and if so, sending a goods shelf moving instruction; wherein the shelf is an integrated movable shelf formed by one or more storage columns. For example, when each cargo space in the shelf completes the release of the corresponding storage object, a move shelf notification is sent to notify the operator 504 to move the shelf out for further processing; for example, in applications where the shelf is used as a seeding wall, the goods within the seeding wall are seeded into the corresponding order box; for example, in applications where the shelves store order boxes, the shelves are moved to a review packing area.

In some embodiments, the picking robot has a first driving wheel set capable of moving in the same direction along a first direction and a second driving wheel set capable of moving in the same direction along a second direction; controlling a transfer robot having a transfer device to move along a rail system on top of a storage unit includes:

controlling the first driving wheel set to leave the track of the track system, and controlling the second driving wheel set to drive the picking and transporting robot to move along the track in the second track set; alternatively, the first and second electrodes may be,

and controlling the second driving wheel set to leave the track of the track system, and controlling the first driving wheel set to drive the picking and transporting robot to move along the track in the first track set.

In some embodiments, further comprising: and controlling the transfer robot to charge the energy storage device of the transfer device in the movement process of the transfer robot along the track system. For example, in the case of the picking and transporting robot shown in the figure, during the movement of the picking and transporting robot along the rail system, the first connecting end is in contact with the second connecting end, and the battery of the picking and transporting robot charges the energy storage device, so that the energy storage device can provide enough electric quantity for the first driving device when the transfer device is used for next transfer, and the first driving device drives the transfer member to complete the transfer.

In some embodiments, further comprising: and determining the transfer direction of the transfer device according to the adjacent position relation between the target position and the target storage column so as to control the transfer device to transfer the storage object between the target storage layer and the target storage layer according to the transfer direction. For example, in the case of the transfer robot shown in fig. 6 to 10, referring to the drawing, when the transfer robot is located at the mark 4 and the target storage column is 4_L, that is, the adjacent position relationship between the target position and the target storage column is that the target position is located on the adjacent right side of the target storage column, and the determined unloading direction is left, the driving roller may be rotated counterclockwise, the driving belt may be moved leftward, and the storage object may be unloaded to the target storage column 4_L. If the picking robot is positioned at the mark 4 and the target storage column is 4_R, namely the adjacent position relation between the target position and the target storage column is that the target position is positioned at the adjacent left side of the target storage column, and the determined unloading direction is right, the driving roller can be rotated clockwise, the belt is driven to move rightwards, and the storage object is unloaded to the target storage column 4_R.

A warehousing system of another embodiment of the present application includes at least one warehousing unit and at least one handling robot:

the warehousing unit comprises a support, a platform track system arranged at the vertical top of the support and a plurality of storage columns arranged below the platform track system, wherein each storage column is provided with a plurality of storage layers which are vertically arranged;

and a transfer robot having a transfer device for lowering the transfer device to a position corresponding to a target storage layer of the target storage row on the side after moving to a target position of the platform rail system, and unloading the storage object from the transfer device to the target storage layer or loading the storage object from the target storage layer to the transfer device.

The present application also provides a management device control unit 600 comprising at least one processor 610 and at least one memory 620, the at least one memory 610 having executable code stored thereon, which when executed by the at least one processor 610, causes the at least one processor 610 to perform some or all of the methods described hereinabove. It will be appreciated that the management device may be one management terminal or one management server, or may also be a collection of one or more management terminals and/or one or more management servers.

The application also provides a pick and place robot control unit 360, including: at least one processor 362, and at least one memory 364, the at least one memory 364 having executable code stored thereon, which when executed by the at least one processor 362 causes the at least one processor 362 to perform some or all of the methods described above.

The Processor 610 or 362 may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

Storage 620 or 364 may include various types of storage units, such as system memory, read Only Memory (ROM), and permanent storage. Wherein the ROM may store static data or instructions for the processor or other modules of the computer. The persistent storage device may be a read-write storage device. The persistent storage may be a non-volatile storage device that does not lose stored instructions and data even after the computer is powered off. In some embodiments, the persistent storage device employs a mass storage device (e.g., magnetic or optical disk, flash memory) as the persistent storage device. In other embodiments, the permanent storage may be a removable storage device (e.g., floppy disk, optical drive). The system memory may be a read-write memory device or a volatile read-write memory device, such as a dynamic random access memory. The system memory may store instructions and data that some or all of the processors require at runtime. Further, the memory may comprise any combination of computer-readable storage media, including various types of semiconductor memory chips (DRAM, SRAM, SDRAM, flash memory, programmable read-only memory), magnetic and/or optical disks, may also be employed. In some embodiments, the memory may include a removable storage device that is readable and/or writable, such as a Compact Disc (CD), a digital versatile disc read only (e.g., DVD-ROM, dual layer DVD-ROM), a Blu-ray disc read only, an ultra-dense disc, a flash memory card (e.g., SD, min SD, micro-SD, etc.), a magnetic floppy disk, and the like. Computer-readable storage media do not contain carrier waves or transitory electronic signals transmitted by wireless or wired means.

Furthermore, the method according to the present application may also be implemented as a computer program or computer program product comprising computer program code instructions for performing some or all of the steps of the above-described method of the present application.

Alternatively, the present application may also be embodied as a non-transitory machine-readable storage medium (or computer-readable storage medium, or machine-readable storage medium) having stored thereon executable code (or a computer program, or computer instruction code) that, when executed by a processor of an electronic device (or electronic device, server, etc.), causes the processor to perform some or all of the steps of the above-described methods according to the present application.

The above description is only a preferred embodiment of the present application and should not be taken as limiting the present application, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

The technical solution according to the present application has been described in detail above with reference to the accompanying drawings.

Having described embodiments of the present application, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen in order to best explain the principles of the embodiments, the practical application, or improvements made to the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (17)

1. Warehousing system, characterized by, include at least one warehouse unit and at least one take and carry robot that has a transfer device:

the warehousing unit comprises a support, a platform track system arranged at the vertical top of the support and a plurality of storage columns arranged below the platform track system, wherein the storage columns are provided with a plurality of storage layers arranged along the vertical direction;

the pick-and-place robot is configured to lower the transfer device to a position corresponding to a target storage tier of a target storage row on a side after moving to a target position of the platform rail system, and unload the storage object from the transfer device to the target storage tier or load the storage object from the target storage tier to the transfer device.

2. The warehousing system of claim 1, wherein:

the storage unit comprises shelf units arranged at intervals along a first direction, and the shelf units comprise at least two storage columns arranged along a second direction;

the target position corresponds to a spacing region between the shelf units spaced apart in the first direction.

3. The warehousing system of claim 2, wherein:

at least two of the storage columns of the shelving units form a unitary structure that is integrally movable relative to the rack; alternatively, the first and second electrodes may be,

at least two of the storage columns of the shelving units form a unitary structure with the rack.

4. The warehousing system of claim 2, wherein:

at least two of the storage columns of the shelving units form a unitary structure that is integrally movable relative to the rack;

the rack and the rack unit do not interfere with each other in the second direction, so that the rack unit can be moved out of the storage unit in its entirety in the second direction.

5. The warehousing system of claim 1, wherein:

the support and the platform rail system form an integral structure;

the system comprises a plurality of the warehousing units, and a plurality of platform rail systems of the warehousing units are butted, so that the picking robot can move among the platform rail systems.

6. The warehousing system of claim 2, wherein:

the bracket and/or the shelf unit are/is provided with a guide rail for guiding the shifting device to ascend and descend.

7. The warehousing system of claim 1, wherein said platform track system edge is provided with a transfer opening for said pick-and-place robot to load or unload said stored objects.

8. The warehousing system of claim 7, further comprising:

an elevator including a ground operating platform and an elevating conveyor for transferring the storage objects between the ground operating platform and the pick-and-place robot at the transfer port; and/or the presence of a gas in the gas,

the ascending ladder is used for an operator to ascend to the transfer port so as to throw the storage object to the picking and transporting robot at the transfer port; and/or the presence of a gas in the gas,

and the automatic conveying line is matched with the height of the platform track system and is used for automatically throwing the storage objects to the pick-and-transport robot at the transfer port or providing the storage objects to an operator on the ascending ladder so that the operator can manually throw the storage objects to the pick-and-transport robot at the transfer port.

9. The warehousing system of any of claims 1-8, wherein the platform track system comprises a first track group and a second track group, the first track group comprising a plurality of tracks extending in a first direction, respectively, the second track group comprising a plurality of tracks extending in a second direction, respectively, the plurality of tracks of the first track group and the plurality of tracks of the second track group forming a plurality of grids, the plurality of grids forming a first grid area and a second grid area, the target storage column being located below the second grid area.

10. The warehousing system of any of claims 1-8, wherein the pick-and-place robot comprises:

the movable base is used for driving the picking robot to move;

the transfer device comprises a transfer piece and a first driving device for driving the transfer piece;

and a lifting device including a lifting mechanism and a second driving device for driving the lifting mechanism, wherein the lifting mechanism is connected to the transfer device, and the second driving device is mounted on the movable base and is used for driving the lifting mechanism to lower the transfer device relative to the movable base to a position corresponding to the target storage layer, so that the transfer member is driven by the first driving device to unload the storage object from the transfer device to the target storage layer or load the storage object from the target storage layer to the transfer device.

11. The warehousing system of claim 10,

the first driving device is configured to drive the transfer member to move forward or backward, so that the transfer member unloads the storage objects from the transfer device to one side when moving in the forward direction and unloads the storage objects from the transfer device to the other side when moving in the backward direction; alternatively, the transfer member may be configured to load one of the storage objects on the transfer device when the transfer member moves in the forward direction and to load the other of the storage objects on the transfer device when the transfer member moves in the reverse direction.

12. The warehousing system of claim 10,

the movable base comprises a main body, a first driving wheel set and a second driving wheel set, wherein the first driving wheel set can move along the first direction in the same direction, and the second driving wheel set can move along the second direction in the same direction;

the first driving wheel set and/or the second driving wheel set are arranged on the main body in a liftable mode.

13. The warehousing system of claim 10, wherein the transfer robot further comprises an energy storage device for powering the first drive device, the energy storage device being connected to a battery mounted to the movable base.

14. The warehousing system of claim 13, wherein:

the energy storage device is arranged on the transfer device; the moving and carrying device is provided with a first electric connection end connected with the energy storage device, and the movable base is provided with a second electric connection end connected with the battery;

the first and second electrical connection ends are configured to contact when the transfer device is in a retracted state, phase-separated in a descending movement of the transfer device.

15. The warehousing system of claim 10, wherein the body of the movable base is an annular body extending through both ends in a lifting direction of the transfer device.

16. The warehousing system of claim 15, wherein:

the vertical size of the transfer device is smaller than that of the movable base;

the overall size of the transfer device in the transverse direction is smaller than the transverse size of an inner hole formed by the inner ring wall of the annular body;

the transfer device is accommodated in the inner hole in a retracted state.

17. A sorting processing system comprising a warehousing system as claimed in any one of claims 1 to 16; the picking and transporting robot is configured to load sorted goods from a rotary packaging port, and unload the sorted goods to the target storage layer after the transferring device descends to a position corresponding to the target storage layer.

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