CN212049032U - Stereoscopic warehouse - Google Patents

Abstract

The utility model discloses a stereoscopic warehouse, which comprises a goods shelf area, wherein a rotary goods shelf, a lifting machine, a conveying device and a first manipulator are arranged in the goods shelf area; the assembly line area is provided with a main conveying assembly line, a telescopic conveying device, a warehousing conveying line and a delivery conveying line; the main conveying assembly line is connected with each conveying device; the first manipulator is used for picking and placing the goods on the conveying device onto the main conveying assembly line; the warehousing conveying line and the ex-warehouse conveying line are respectively and vertically intersected and connected with the main conveying pipeline, and the warehousing conveying line is provided with a warehousing coded disc manipulator for coding the goods conveyed by the telescopic conveying device to the warehousing conveying line; and the delivery code disc manipulator is arranged at the delivery conveying line and used for coding the goods on the delivery conveying line to the transportation equipment. According to the stereoscopic warehouse, the requirements of 'whole support and frame entering and single piece ex-warehouse' are simply and efficiently realized through a mode of combining the rotary goods shelf, the hoister, the manipulator and the assembly line; meanwhile, the rotary goods shelf can effectively improve the space utilization rate of the warehouse.

Description

Stereoscopic warehouse

Technical Field

The utility model relates to a logistics storage technical field especially relates to a stereoscopic warehouse.

Background

With the rapid development of the logistics industry and the manufacturing industry, the automation technology and the information technology are rapidly improved, and the traditional warehouse gradually upgrades to modernization, automation and intellectualization. At present, the automatic stereoscopic warehouse is more and more widely applied to the logistics industry due to the operation efficiency. In the existing stereoscopic warehouse, in order to facilitate forklift operation, the distance between the goods shelves is about 3.5 meters, the spacing distance between the goods shelves is large, and the warehouse area utilization rate is low.

Meanwhile, in the process of warehousing and delivery of goods, in order to realize 'whole-pallet loading and unloading' and 'single-piece warehousing and delivery', a generally adopted method is to stack single-piece goods on a pallet during warehousing and then carry the goods to a storage area by equipment; when the goods are delivered out of the warehouse, the whole goods are required to be transported to a goods preparation area, and the whole goods are transported back to the storage area after the single goods are taken out. Under the business mode of B2C, the warehouse faces the client, the product delivery has the characteristics of small batch and multiple types, the required quantity of the same type of products in each order is less, and the requirement for implementing single delivery is obviously improved. However, the operation mode of 'whole support frame entering and single piece ex-warehouse' of the existing stereoscopic warehouse wastes a large amount of manpower and material resources.

SUMMERY OF THE UTILITY MODEL

Based on this, the to-be-solved technical problem of the utility model is to provide a simple efficient stereoscopic warehouse of high storehouse space utilization, "put in order, put out of stock" of putting in order.

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

a stereoscopic warehouse, comprising:

the goods shelf area is provided with a plurality of rotary goods shelves which can make goods rotate, and a lifting machine, a conveying device and a first manipulator which are arranged at two ends of each rotary goods shelf; the hoister is used for taking and placing goods from the rotary goods shelf;

the assembly line area is provided with a main conveying assembly line, a telescopic conveying device, a warehousing conveying line and a delivery conveying line; the telescopic conveying device is used for connecting the platform; the main conveying assembly line is arranged along the width direction of the rotary goods shelf and is connected with each conveying device; the first manipulator is arranged on one side of the conveying device and used for picking and placing the goods on the conveying device onto the main conveying assembly line; the warehousing conveying line and the ex-warehouse conveying line are respectively vertically and crosswise connected with the main conveying assembly line, and the warehousing conveying line is provided with a warehousing coded disc manipulator for coding the goods conveyed by the telescopic conveying device to the warehousing conveying line; and the delivery conveying line is provided with a delivery code wheel manipulator which is used for coding the goods on the delivery conveying line to the transportation equipment.

Furthermore, the main conveying assembly line comprises a plurality of assembly line units which can be driven independently, and the conveying device and the ex-warehouse conveying line are respectively butted with the assembly line units; the assembly line unit is provided with a steering mechanism, and can enable goods to be correspondingly conveyed to the conveying device and the delivery line from the main conveying assembly line in a steering mode.

Furthermore, the main conveying assembly line is of an annular structure, and the warehousing conveying line and the warehousing coded disc manipulator are arranged inside the main conveying assembly line; the height of the telescopic conveying device is lower than that of the main conveying assembly line, one end of the telescopic conveying device is connected with the platform, and the other end of the telescopic conveying device extends into the main conveying assembly line.

Furthermore, one end, far away from the goods shelf area, of the delivery conveying line is located outside the main conveying flow line, and the delivery coded disc manipulator is arranged on one side of the delivery conveying line located outside the main conveying flow line.

Further, the rotary shelf comprises a shelf body and a multi-layer shelf unit arranged on the shelf body; the goods shelf unit comprises a plurality of laid rollers and a first gear chain mechanism for driving the rollers to rotate.

Further, a storage position plate is arranged on the shelf unit, an electronic tag is arranged on the storage position plate, the storage position plate is arranged on the roller and is driven by a storage position driving mechanism, and the movement speed of the storage position plate is the same as the conveying speed of the conveying assembly.

Further, the conveying device is a chain guide rail conveyor.

Furthermore, a detection component is arranged on the main conveying pipeline and used for detecting whether goods reach the pipeline unit.

Further, the detection part includes a photoelectric switch.

Compared with the prior art, the utility model discloses an advantage is with positive effect:

above-mentioned stereoscopic warehouse, the mode that combines together through rotation type goods shelves, lifting machine, manipulator and assembly line realizes "whole support frame, the requirement of single ex-warehouse" simply high-efficiently: when the goods are put in storage, the goods are grabbed to the code disc area and coded by the code disc mechanical hand, and then the whole support is transported to a goods shelf along with a production line and a lifting machine. When the single goods are delivered out of the warehouse, the whole goods on the high-rise goods shelf are conveyed to the bottommost layer by the elevator, and then the single goods are taken out by the first mechanical arm and placed on the production line to be conveyed to the spare goods area, so that the single goods can be delivered out of the warehouse. Meanwhile, the rotary goods shelves can be arranged side by side without intervals, and the utilization rate of warehouse space is effectively improved.

Other features and advantages of the present invention will become more apparent from the following detailed description of the invention when read in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic plan view of a stereoscopic warehouse of the present invention;

fig. 2 is a schematic plan view of a pipeline area in a stereoscopic warehouse according to the present invention;

fig. 3 is a schematic perspective view of a pipeline area in a stereoscopic warehouse according to the present invention;

fig. 4 is a detailed structure diagram of the pipeline area in the stereoscopic warehouse of the present invention;

fig. 5 is a partial structure view of the rotary shelf in the stereoscopic warehouse of the present invention;

FIG. 6 is an enlarged view of FIG. 5;

description of reference numerals:

a rotary shelf 100; a roller 110; a library site plate 120; a second gear 131; a second chain 132; a second motor 133; a second gear set 134; a first accessory plate 140; a second accessory plate 150; elongated holes 151; a fastener 160;

a hoist 200;

a conveying device 300;

a first robot 400;

a main transport stream line 510; a pipeline unit 511; a detection section 512; a warehousing conveyor line 520; an ex-warehouse conveying line 530;

a telescopic conveyor 600;

a warehouse entry code wheel manipulator 710; and an ex-warehouse code disc manipulator 720.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings and embodiments.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 6, in order to illustrate an embodiment of the stereoscopic warehouse of the present invention, referring to fig. 1, the stereoscopic warehouse is mainly divided into a shelf area a, a pipelining area B, AGV, a guiding route area C, and a stock area D.

The rack area a is provided with a rotary rack 100, a hoist 200, a conveying device 300, and a first robot 400.

A plurality of rotary racks 100 are arranged side by side in the central area of the stereoscopic warehouse, and each rotary rack 100 is arranged perpendicular to the direction of the platform. The area of the rotary shelf 100 located in front and back is symmetrical about the center of the warehouse as shown in fig. 1 and 2. The rotary shelf 100 includes a shelf body, and a plurality of shelf units provided on the shelf body, and goods can be rotated on each shelf unit. Each layer of shelf unit can be independently controlled and can independently rotate in the forward direction and the reverse direction. The two ends of the rotary shelf 100 are the goods inlet and outlet.

The hoists 200 are placed at both ends of the rotary shelf 100. After the terminal sends the order information, the warehouse management system controls the goods shelf unit of the goods layer to rotate, the goods are rotated to the goods inlet and outlet at two ends, and then the goods carrying tray is forked by the elevator 200, so that the goods move in the vertical direction.

The conveyor 300 is preferably a chain guide conveyor, and the conveyor 300 is used in conjunction with the elevator 200 and the pipeline. When the goods are delivered out of the warehouse, the lifter 200 places the goods with the bracket on the track of the chain guide rail conveyor, and the track drives the goods to the front end pipeline area; when the goods are put in storage, the chain guide rail conveyor drives the goods to the upper rack opening from the assembly line area to wait for the elevator 200 to fork and lift.

The first manipulator 400 is responsible for sucking the goods in the required quantity for delivery from the pallets on the conveyor 300, and the first manipulator 400 places the goods one by one in the assembly line area.

The flow line area B is provided with a main transport flow line 510, a telescopic transport device 600, a warehousing transport line 520, and an ex-warehouse transport line 530.

As shown in fig. 2, the main conveying line 510 is disposed along the width direction of the rotary rack 100 and connected to each of the conveying devices 300.

The telescopic conveyor 600 is used to connect a platform. The single piece goods are unloaded from the vehicle and placed on the telescopic conveyor 600.

The warehousing conveying line 520 is perpendicularly connected with the main conveying pipeline 510 in an intersecting mode. The warehousing coded disc manipulator 710 is arranged at the warehousing conveying line 520 and used for coding the single goods conveyed by the telescopic conveying device 600 to the tray on the warehousing conveying line 520 and then conveying the single goods to the main conveying line 510 through the warehousing conveying line 520.

Similarly, the delivery line 530 is connected to the main delivery line 510 in a perpendicular intersecting manner. The delivery code disc manipulator 720 is arranged at the delivery conveying line 530 and is used for carrying the single goods on the delivery conveying line 530 to the pallet on the conveying equipment during delivery operation, and then the conveying equipment conveys the pallet to the goods preparation area. In this embodiment, the transport is an AGV.

The AGV guiding route area C is used for planning and transporting the AGV route, provides guidance and a route for the AGV, and smoothly links the goods transfer between the assembly line area and the stock area. The stock areas D are arranged on two sides of each warehouse door.

All areas of the stereoscopic warehouse cooperate with each other according to the warehouse-in and warehouse-out process, and the warehouse-in and warehouse-out operation in the automatic stereoscopic warehouse is realized together. When goods are delivered from a warehouse, the warehouse management system controls the goods shelf where the target goods are located to rotate, the whole goods are transferred to the goods taking port, the elevator 200 takes the goods down and places the goods on the conveying device 300, the conveying device 300 conveys the goods to the butt joint of the main conveying pipeline 510, the single pieces are placed on the main conveying pipeline 510 and then output through the delivery conveying line 530, single pieces are delivered from the warehouse, the single pieces on the delivery conveying line 530 are coded on the AGV tray through the delivery coded disc manipulator 720, and then the AGV conveying tray is placed in the spare goods area. When goods are warehoused, the telescopic conveying device 600 conveys single goods to the warehousing coded disc manipulator 710, the warehousing coded disc manipulator 710 conveys the single goods coded disc to the main conveying flow line 510 through the warehousing conveying line 520, the single goods are conveyed to the conveying device 300 in front of the target shelf through the main conveying flow line 510, and finally the whole goods are forked to the rotary shelf 100 through the elevator 200, so that the whole goods are completely held in the shelf.

The stereoscopic warehouse simply and efficiently meets the requirements of 'whole support in rack and single piece out of warehouse' through the mode of combining the rotary goods shelf 100, the hoister 200, the manipulator and the production line: when the goods are put in storage, the storage coded disc manipulator 710 grabs the goods to the coded disc area and codes the goods, and then the whole support is transported to a shelf along with the production line and the elevator 200. When the single goods are delivered out of the warehouse, the elevator 200 transports the whole consignment on the high-rise shelf to the bottommost layer, and the first mechanical arm 400 takes out the single goods and puts the single goods on the production line to be conveyed to the spare goods area, so that the single goods can be delivered out of the warehouse. Meanwhile, the rotary type goods shelves 100 can be arranged side by side without intervals, and the utilization rate of the warehouse area is effectively improved.

In this embodiment, as shown in fig. 4, the main conveying line 510 is a roller driving structure, the main conveying line 510 includes a plurality of line units 511 capable of being driven individually, and the conveying device 300 and the delivery line 530 are respectively connected to the line units 511. The line unit 511 has a diverting mechanism (not shown) capable of diverting the goods from the main conveying line 510 to be conveyed correspondingly to the conveying device 300 and the delivery line 530. That is, the goods are diverted from the main conveying line 510 to the conveying device 300 by the diverting mechanism through the line unit 511 at the control gate during warehousing, and the goods are diverted from the main conveying line 510 to the delivery conveying line 530 by the diverting mechanism through the line unit 511 at the control gate during delivery. In this embodiment, the steering mechanism of the line unit 511 comprises a belt capable of ascending and descending, the conveying direction of the belt is perpendicular to the conveying direction of the drum, and the belt drives the goods to steer when ascending. In other embodiments, other steering mechanisms such as a push rod, another set of rollers capable of ascending and descending, and the like can be used for steering the goods.

The main conveying line 510 is of an annular structure, and the warehousing conveying line 520 and the warehousing coded disc manipulator 710 are arranged inside the main conveying line 510. The telescopic conveyor 600 is lower than the main conveying line 510 in height, one end of the telescopic conveyor is connected with the platform, and the other end of the telescopic conveyor extends into the main conveying line 510. One end of the delivery conveying line 530 far away from the goods shelf area is positioned outside the main conveying flow line 510, and the delivery code disc manipulator 720 is arranged on one side of the delivery conveying line 530 positioned outside the main conveying flow line 510 and is convenient to code discs onto the AGV.

The main conveying pipeline 510 is provided with a detection component 512 for detecting whether the goods reach the pipeline unit 511, and further judging whether the goods are diverted. As shown in fig. 4, specifically, the detecting unit 512 includes a photoelectric switch, the photoelectric switch includes an emitting unit for emitting a detecting light and a receiving unit for receiving the detecting light, the emitting unit and the receiving unit are disposed at two sides of the line unit 511, and when the goods pass through, the goods block the detecting light, and the receiving unit does not receive the detecting light, it is determined that the goods reach the line unit 511. The pallets loaded with goods flow to the goods shelves through the pipeline area, the warehouse management system sends shelving information (goods shelf numbers) to the controller of the pipeline area, the controller on the pipeline opens the photoelectric switch corresponding to the pipeline unit 511 at the front crossing of the goods shelves according to the received goods shelf numbers, when the goods are detected, the goods are judged to be the current goods on the goods shelves, the belt of the pipeline unit 511 at the crossing is lifted at the moment, and the goods are driven to turn (meanwhile, the controller in the pipeline area sends a fork goods instruction to the elevator 200).

In this embodiment, the first manipulator 400, the input code wheel manipulator 710 and the output code wheel manipulator 720 are preferably suction cup type manipulators, and the input code wheel manipulator 710 is provided with an OCR bar code automatic scanner for inputting goods information.

In this embodiment, the rotary rack 100 is specifically configured as shown in fig. 5 and 6, and the rotary rack 100 includes a rack body on which a plurality of layers of rack units are disposed, and the rack units include a conveying assembly that is circularly rotated and conveyed, and can make goods rotate on a horizontal plane. The operation of each layer of shelf units is independently controlled, so that the single-layer independent rotation can be realized, the shelf units on the layer where the goods are located can be appointed by the warehouse management system, and the goods are conveyed to the goods sorting port to be picked up. In order to realize that the position of the goods can be determined when the conveying assembly drives the goods to rotate, a plurality of warehouse location plates 120 are arranged on the conveying assembly, the warehouse location plates 120 are used for placing the goods, and electronic tags are arranged on the warehouse location plates 120. When the tray is placed on the storage position plate, the tray is bound with the storage position, so that the position of the goods on the goods shelf can be determined. The storehouse position plate 120 is arranged on the conveying assembly, and is driven to rotate by the conveying assembly, and meanwhile, the rotation is realized by the storehouse position driving mechanism, so that the movement speed of the storehouse position plate 120 is the same as the conveying speed of the conveying assembly, and the binding and stable transfer of goods are realized.

According to the rotary shelf, the storage position plates 120 are arranged on the conveying assembly, the trays and goods are placed, the storage position driving mechanism keeps the operation at the same speed as the conveying assembly, so that the positions of the storage position plates 120 can be kept unchanged relatively in the rotation process of the storage position plates 120, and the positions of the goods on the shelf units can be determined through the electronic tags, so that the goods can be conveniently delivered out of the warehouse and put in the warehouse.

In this embodiment, the transfer assembly includes a number of rollers 110 and a first gear chain mechanism (not shown). A plurality of rollers 110 are laid to form an annular conveying track, and a first gear chain mechanism is used for driving the rollers 110 to rotate. The magazine plate 120 is placed on the roller 110. Specifically, the first gear-chain mechanism includes first gears disposed at two ends of the roller 110, a first chain engaged with the first gears, and a first driving member for driving the first chain to rotate. The first drive member is preferably a first motor, which is an adjustable speed motor. The chain transmission in the embodiment has no elastic sliding and slipping phenomena, accurate average transmission ratio, reliable work and high efficiency.

As shown in fig. 5, the magazine driving mechanism for driving the magazine plate 120 to move includes a second gear 131 chain mechanism, and the second gear 131 chain mechanism includes: the second gear 131, the second chain 132 and the second motor 133, the second gear 131 is disposed at two ends of the inside of the annular conveying track, and the rotation axis of the second gear set 134 is in the vertical direction. The second chain 132 is engaged with the second gear 131; the second motor 133 is drivingly connected to the second gear 131 through a drive gear set. The second chain 132 is fixedly connected with the storage location plate 120 through a fixing member.

Specifically, referring to fig. 6, the fixing member includes a plurality of accessory plates fixed to the chain, and the magazine plate 120 is fixedly connected to the plurality of accessory plates by a fastening member 160. The fasteners 160 are preferably rivets. The attachment plates are projection welded or fillet welded to the link plates on one side of the chain.

In this embodiment, the attachment plate is fixed to the upper side of the chain, with the attachment plate being horizontally disposed. The accessory plates include a first accessory plate 140 and a second accessory plate 150. The first attachment plate 140 is formed with circular holes for receiving fasteners 160, and preferably the first attachment plate 140 is fixed to the magazine plate 120 at a middle position of a side edge thereof. The second attachment plates 150 are disposed on both sides of the first attachment plate 140, and in this embodiment, the second attachment plates 150 are provided with two elongated holes 151 for mounting the fastening members 160, and the length direction of the elongated holes 151 is disposed along the axial direction of the drum 110. By providing the elongated hole 151, when the storage plate 120 is moved to the arc sections at both ends, the fastening member 160 can slide in the elongated hole 151, so as to ensure that the storage plate 120 can complete the turning motion.

In this embodiment, the material of the storage location plate 120 is preferably a galvanized steel plate with a thickness of 1mm, the upper surface is attached with staggered line protrusions to increase the friction force, and the lower surface is smooth to facilitate the movement on the roller.

The warehouse management system is connected with the shelves through wireless communication technology, such as zigbee. Because the goods stop to receive the inertia effect and need just can stop through the buffering, can stably stop at the goods shelves port according to atress analysis goods in the junction change speed in goods shelves arc region and sharp region. In order to ensure that the goods and the tray do not move relatively when stopping, under the condition that the goods are delivered out of the warehouse, the goods shelf starts to decelerate when the goods delivered out of the warehouse are conveyed to the intersection point of the arc-shaped track and the linear track, and the goods shelf stops completely when reaching the goods outlet.

In this embodiment, each layer of shelf unit is provided with a radio frequency module at the outlet, the radio frequency module can be fixed inside the shelf beam, the center of each storage plate 120 is provided with an electronic tag, and the radio frequency module transmits a radio frequency signal and is connected with the control chip of each layer of shelf unit through a wire.

The principle of the storage plate 120 in the rotary shelf 100 of the utility model is as follows: when goods need to go in and out of the shelf, the control system sends out specific storage position signals which are required to be stored by the goods, the goods shelf receives information, the control chip controls the layer of goods shelf units to rotate, and in the rotating process of the goods shelf, the radio frequency module can identify radio frequency electric waves reflected by the electronic tags on different storage position plates 120. When the radio frequency module identifies the target warehouse location plate 120, the radio frequency module sends a digital signal to the control center, the control chip immediately makes a response, the rotation of the shelf unit is stopped, the goods can be stopped at the port, and the vehicle loading hoister 200 can load the goods into the shelf.

The warehousing process of the stereoscopic warehouse is as follows:

after the truck stops at a platform, goods are placed on the telescopic conveying device 600 in a single piece mode, the goods reach the warehousing coded disc manipulator 710 through the telescopic conveying device 600, the warehousing coded disc manipulator 710 scans the goods and sucks the goods from the telescopic conveying device 600 to a coded disc area (an empty tray is arranged on the coded disc area and is in a static state) on the warehousing conveying line 520, warehousing operation is carried out, and the coded disc and information input of the goods are carried out at the same time; the manipulator stacks the goods reasonably according to the overall dimension of the goods and judges whether the goods are stacked, the warehousing conveying line 520 drives the trays to the main conveying line 510 after the stacking is completed, and the warehousing coded disc manipulator 710 absorbs the next empty tray to the coded disc area on the warehousing conveying line 520 to wait for the next goods loading operation.

The pallets loaded with goods flow to the shelves through the main conveying pipeline 510, the warehouse management system sends shelving information (shelf numbers) to the controller of the pipeline area, the controller opens the photoelectric switch corresponding to the pipeline unit 511 at the front crossing of the shelves according to the shelf numbers received, when the goods are detected, the goods are judged to be the current shelf goods, the belt of the pipeline unit 511 at the crossing is lifted at the moment, the goods are driven to turn (meanwhile, the controller in the pipeline area sends a fork goods instruction to the elevator 200), and the goods reach the chain guide rail conveyor at the shelving crossing.

At this time, the elevator 200 has received the fork goods instruction, the fork extends into the gap at the lower end of the tray, the rotary shelf 100 starts to operate at this time, the rotary shelf is rotated out of the empty warehouse location, the fork retracts into the shuttle rack, and the elevator 200 is started and lifted to the corresponding goods layer. After the goods reach the corresponding goods layer, the goods are sent out by the fork, and the goods are moved to the storage position in the goods shelf. After the goods are placed, the RFID scanner attached to the fork scans the RFID label on the storage position, and the information binding of the goods and the storage position, namely the dynamic binding of the goods and the placement position of the tray, is realized. The fork retracts into the elevator 200, the elevator 200 descends to the upper rack opening, one-time operation is completed, and the next operation is waited.

The ex-warehouse process is as follows:

when the goods are delivered out of the warehouse, the elevator 200 rises to a goods layer where the goods on the lower shelf are located, meanwhile, the warehouse management system sends an instruction to the rotary type goods shelf 100, the corresponding goods lattice is transferred out according to the principle that the first-in first-out is the highest priority, the first-out of the tray which is not full is the second priority, the first-out of the goods close to the goods outlet is the third priority, the elevator 200 stretches out the fork to take the tray, retracts into the elevator 200, and the elevator 200 descends to the goods outlet.

After the goods arrive at the opening of the lower rack, the forks move the goods of the whole pallet to the chain guide rail conveyor outside the lifting frame, the first mechanical arm 400 sucks the goods to the main conveying line 510 in a single piece mode according to the quantity required by the truck list, and the goods flow through the main conveying line 510 to move to the delivery conveying line 530. After the goods reach the delivery port of delivery conveyor 530, AGV back-picks up empty tray to the delivery port other delivery code wheel manipulator 720 limit from empty tray placing area (spare goods area) this moment, and delivery code wheel manipulator 720 carries out the code wheel operation according to algorithm design, and after the code wheel finishes, AGV transport goods to the spare goods district.

When the AGV carries goods to the stock area, the principle that the goods of first-out are swung to the position close to the outer ring is needed, so that the problem that the goods in the inner layer cannot be carried out due to insufficient turning space when the forklift carries the goods to the platform can be avoided.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or that equivalents may be substituted for elements thereof; such modifications and substitutions do not depart from the spirit and scope of the present invention, which is claimed.

Claims (9)

1. A stereoscopic warehouse, comprising:

the goods shelf area is provided with a plurality of rotary goods shelves which can make goods rotate, and a lifting machine, a conveying device and a first manipulator which are arranged at two ends of each rotary goods shelf; the hoister is used for taking and placing goods from the rotary goods shelf;

the assembly line area is provided with a main conveying assembly line, a telescopic conveying device, a warehousing conveying line and a delivery conveying line; the telescopic conveying device is used for connecting the platform; the main conveying assembly line is arranged along the width direction of the rotary goods shelf and is connected with each conveying device; the first manipulator is arranged on one side of the conveying device and used for picking and placing the goods on the conveying device onto the main conveying assembly line; the warehousing conveying line and the ex-warehouse conveying line are respectively vertically and crosswise connected with the main conveying assembly line, and the warehousing conveying line is provided with a warehousing coded disc manipulator for coding the goods conveyed by the telescopic conveying device to the warehousing conveying line; and the delivery conveying line is provided with a delivery code wheel manipulator which is used for coding the goods on the delivery conveying line to the transportation equipment.

2. The stereoscopic warehouse of claim 1, wherein the main conveying line comprises a plurality of individually driven line units, and the conveying device and the ex-warehouse conveying line are respectively butted against the line units; the assembly line unit is provided with a steering mechanism, and can enable goods to be correspondingly conveyed to the conveying device and the delivery line from the main conveying assembly line in a steering mode.

3. The stereoscopic warehouse of claim 2, wherein the main conveying line is of an annular structure, and the warehousing conveyor line and the warehousing coded disc manipulator are arranged inside the main conveying line; the height of the telescopic conveying device is lower than that of the main conveying assembly line, one end of the telescopic conveying device is connected with the platform, and the other end of the telescopic conveying device extends into the main conveying assembly line.

4. The stereoscopic warehouse of claim 3 wherein the end of the outbound conveyor line remote from the shelf area is located outside the main conveyor line, and the outbound code wheel robot is disposed on the side of the outbound conveyor line located outside the main conveyor line.

5. The stereoscopic warehouse of any one of claims 1 to 4, wherein the rotary rack comprises a rack body, and a multi-shelf unit disposed on the rack body; the goods shelf unit comprises a conveying assembly, wherein the conveying assembly comprises a plurality of laid rollers and a first gear chain mechanism for driving the rollers to rotate.

6. The stereoscopic warehouse of claim 5, wherein the shelf units are provided with warehouse location plates, the warehouse location plates are provided with electronic tags, the warehouse location plates are arranged on the rollers, and the warehouse location plates are driven by a warehouse location driving mechanism, so that the movement speed of the warehouse location plates is the same as the conveying speed of the conveying assembly.

7. Stereoscopic warehouse according to claim 1, characterized in that the conveying means are chain guide conveyors.

8. Stereoscopic warehouse according to claim 2, characterized in that the main conveying line is provided with detection means for detecting whether the goods reach the line units.

9. Stereoscopic warehouse according to claim 8, characterized in that the detection means comprise an optoelectronic switch.

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