JPS61114907A - Entry/delivery mechanism of rotary storehouse - Google Patents

Abstract

PURPOSE:To reduce entry/delivery labor hour and to expedite the delivery by providing a plurality of lifters for the exclusive use for entry portion and delivery portion respectively. CONSTITUTION:A plurality of delivery lifters 15 are arranged at equal spaces on an delivery portion 4, and guided by a long oval lifter guide 17 to be verti cally elevated and turned extending over multi-stage rotary racks 11,12.... A delivery conveyer 5 is disposed at a space equal to the interval between rotary racks below the lowermost rotary rack 11, and at that position, a container feed-out mechanism 18 of the delivery lifter 15 is driven to transfer a container 2 onto the conveyer 5. The other delivery lifters 15 are respectively stopped at delivery gates 9 of the other rotary racks. For example, the second lifter 15 is stopped at the rack I2, and the third lifter at the rack I4 to receive delivered goods from each gate 9. Thus, a plurality of entry/delivery lifters for exclusive use are disposed to expedite entry/delivery operation.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an improvement in a loading/unloading mechanism for a rotary type warehouse.

In recent years, rotary type warehouses as shown in FIG. 2 have been provided for the purpose of streamlining warehouse operations and speeding up loading and unloading operations.

In FIG. 2, a rotary type warehouse consists of rotary racks 1. .

1z, 13.-4n are installed vertically in multiple stages.

Each rotary rack can be rotated forward or backward as desired, and an address is designated for each portion on which the container 2 is mounted. Then, the selected address of the rotary rack selected by a command from a control device (not shown) is configured to be stopped in the warehousing section 3 and the warehousing section 4, respectively.

A warehousing lifter 38 and a warehousing competition 73B are installed in the warehousing section 3 at a desired location of the rotary racks mounted in multiple stages, and when desired parts are manually placed in the container 2 and placed on the warehousing conveyor 3B, The container 2 is automatically transferred to the warehousing conveyor 38, the selected rotary rack rotates, the designated empty address stops at the warehousing gate position, the container 2 is transferred to the rotary rack, It is now in stock.

Note that the parts name, quantity, and address of the storage shelf number of the received container 2 are input as data from a terminal and stored in the control device, so that the control device has a function as an inventory ledger.

Further, a delivery section 4 including a delivery lift 6 and a delivery conveyor 5 is installed at a desired location of the rotary racks mounted in multiple stages.

When a request for a desired part is input to the control device from the assembly department, the control device is activated, and the rotary rack on which the container 2 containing the part is mounted turns in the shortest direction. The address stops at the exit gate position of the exit lifter 6.Then, the container 2 is moved to the exit lifter 6.
Then, it is further transferred from the warehouse lifter 6 to the warehouse conveyor 5, and is then discharged and transferred to the assembly department.

Note that the delivered parts are automatically stored as delivered parts, and their addresses are also automatically stored as empty addresses.

In such a warehouse system, the number of parts is extremely large, and in response to random requests from a large number of assembly departments, it is required to quickly and without delay ship out the parts.

[Conventional technology]

In the conventional warehousing/unloading mechanism, both the warehousing section and the warehousing section have substantially the same structure. Therefore, the conventional warehousing and retrieval mechanism will be explained using the warehousing section as an example.

FIG. 3 is a perspective view of a conventional storage section, in which the storage section 4 is
Each rotary rack installed in multiple stages 1. ．． 1
A lifter 6 for taking out the warehouse is installed which moves up and down over □, -4n. A delivery conveyor 5 is installed at the lowest stop position of the delivery lifter 6. Also,
Elevation stop sensors 8 (
For example, a magnetic signal generator (magnetic signal generator) is installed, and a lifter 6 for
A counter is installed that receives and counts signals when the robot moves up and down and passes this up/down stop sensor 8.

The unloading lifter 6 is normally stopped at the position of the unloading conveyor 5, and is raised by being driven as desired by the lifting motor 7 in response to a command from the control device. Also, mll J
The B device instructs the address position of the container 2 containing the outgoing parts to stop at the outgoing gate 9 position.

On the other hand, the control device stops the unloading lifter 6 when the counter counts the position corresponding to the unloading gate 9 of the rotary rack on which the unloading parts are mounted.

Then, the corresponding pusher 10 is driven to transfer the selected container 2 from the rotary rack to the shipping lifter 6. When the transfer is completed, the unloading lifter 6 descends,
It stops at the lowest position of the delivery conveyor 5, and a container delivery mechanism (not shown) is driven to transfer the container 2 to the delivery conveyor 5, and the container 2 is delivered to the assembly department by the delivery conveyor 5.

Regarding the warehousing section 3, the warehousing conveyor 5 shown in FIG.
This is a configuration that has been changed to ^.

In order to put desired parts into the container 2 and store it, the container 2 is transferred from the storage conveyor 3A to the storage lifter 3A. On the other hand, according to a command from the control device, a rotary rack with an empty address is selected from among the designated rotary racks If 1z+ -4n, rotated, and stopped at the warehousing gate position.

The lifting stop sensor 8 causes the warehousing lifter 3A to stop at a designated warehousing gate position, and the container 2 is transferred to an empty address position and warehoved.

[Problem that the invention seeks to solve]

However, the above-mentioned conventional loading/unloading mechanism is only equipped with one lifter for loading and one lifter for loading/unloading. Therefore, the lid, which is stopped at the lowest position, is raised to the specified gate position and the container is transferred from the incoming lifter to the rotary rack, or from the rotary rack to the outgoing lifter. There is.

Therefore, there is a problem in that it takes time for the lifter to move back and forth, and the randomly requested unloading work is delayed.

[Means for solving problems]

The above-mentioned problem with the conventional method is that the storage section is equipped with a plurality of lifters for loading that can rotate up and down as desired, and an unloading section is equipped with a plurality of lifters for loading and unloading that can rotate up and down as desired. The warehousing lifter stops at the warehousing gate corresponding to the nearest empty address position of the rotary rack, transfers the container onto the rotary rack and stores it, and the container whose status has been determined is With the rotary rack stopped so that it is located at the exit gate, the nearest elevator for exit moves to a position corresponding to the exit gate and stops, and the designated container is transferred to the lifter for exit. This problem is solved by the loading and unloading mechanism of the present invention, which is configured to load and unload the storage.

[Effect]

According to the above means of the present invention, since a plurality of warehousing lifters are attached to the warehousing section, while a container is being transferred from the warehousing lifter to the rotary rack, another container is transferred to another warehousing lifter. It is possible to

In addition, the unloading section is also equipped with multiple unloading lifters, so the unloading lifter stopped at the location closest to the desired unloading gate is called up and the selected container is transferred from the rotary rack to the unloading lifter. During the transfer, other containers that have been transferred to other unloading lifters can be transferred to the unloading conveyor.

Therefore, it is possible to quickly and without delay respond to random requests from a large number of assembly departments.

〔Example〕

The gist of the present invention will be specifically explained below with reference to illustrated examples. Note that the same reference numerals indicate the same objects throughout the figures.

1 ′1
In the warehousing/unloading mechanism of the present invention, both the warehousing section and the warehousing section have substantially the same structure. Therefore, the loading/unloading mechanism will be explained by illustrating the loading/unloading section.

FIG. 1 is a perspective view of a delivery section of an embodiment of the present invention,
In the unloading section, a plurality of unloading lifters 15 are arranged in parallel at equal pitches, guided by a vertically long oval lift guide 17, and are installed in multiple stages.
, -・-・-1n so that it can be rotated up and down.

The unloading lifter 15 is equipped with a tiltable arm 16 that opens horizontally when positioned on the rotary rack side and supports the container 2 on its upper surface. In addition, in the illustrated example, the lifter 15 for shipping is the rotary rack 19.1□, .
They are installed at a pitch that is twice the vertical spacing of In.

Then, the shipping conveyor 5 is installed horizontally below the rotary rack 11 at the lowest stage at a position equal to the vertical spacing of the rotary rack, and the shipping lifter 15 is stopped on the same plane as the shipping container 5. Delivery mechanism 18
is driven to transfer the container 2 to the shipping container 5.

Therefore, for example, when the No. 1 unloading lifter 15 is stopped at a position corresponding to the unloading conveyor 5, the No. 2 unloading lifter 15 is at the unloading gate 9 position of the rotary rack 1□, and the No. The unloading lifter 15 is stopped at the unloading gate 9 position of the rotary rack 14. □ For example, at the start of every morning, the origin is adjusted so that the No. 1 unloading lifter 15 is in a position corresponding to the unloading conveyor 5, and the unloading lifter 15 is moved up and down as desired at any time during the operation. The positions of the lifters 15 are stored in the control device.

The rotary racks L, lx, and -4n are also set to the respective rotary racks h by adjusting the origin of the address No. 1 to the exit gate 9, for example, at the start of each morning.

Even if 1□ and -In turn as desired, the control device stores the position at which each address is turning at any given time during operation.

Each rotary rack1. , 1□, and -In are stopped, the rack directional sensor 21 that confirms whether or not the container 2 is loaded at the address designated at the exit gate 9 position is connected to each lift stop sensor 8. It is installed at the exit gate 9 position.

Further, when the unloading lifter 15 stops at the unloading conhair 5 position, it is confirmed that the container 2 is loaded on the unloading lifter 15, and the container delivery mechanism 18 is driven to move the container 2 to the unloading conhair 5. A lifter back sensor 20 is installed near the exit conveyor 5.

Furthermore, the unloading unit sensor 19 recognizes that the container 2 has been transferred to the unloading conveyor 5 from the unloading lifter 15 and transmits to the control device that the unloading lifter 15 is in a driveable state. is installed near the exit conveyor 5.

Since the configuration is as described above, in response to a request from the assembly department, the control device determines the address where the container 2 containing the component is mounted, from the rotary rack lr, to the rotary rack lr,
'h, -1n Ito-- is selected, the selected rotary rack is rotated in the shortest direction, and the container 2 is stopped at the exit gate 9 position.

At the same time as this command, the unloading lifter 15 that is stopped at the position closest to the selected unloading gate 9 (the unloading lifter 15 may be stopped at the unloading gate position) is called, and the unloading lifter 15 is called. is stopped, and after the rack directional sensor 21 confirms the container 2 on the rotary rack, the pusher 10 is driven to move the selected container 2.
is transferred to the unloading lifter 15 in the selection section.

When the transfer is completed, the unloading lifter 15 is moved to the unloading conveyor 5.
The container 2 is lowered to the position shown in FIG.

In addition, if another warehouse lifter 15 is stopped at the desired warehouse gate 9 while being transferred to this warehouse conveyor 5,
The next container 2 can be transferred to the shipping lifter 15 by rotating the rotary rack.

Furthermore, the warehousing section 3 has a configuration in which the warehousing conveyor 5 in FIG. 1 is replaced with an warehousing conveyor, and the warehousing lifter 15 is replaced with a warehousing lifter.

That is, in order to put desired parts into the container 2 and store the parts, the container 2 is transferred from the warehousing conveyor to the desired warehousing lifter. On the other hand, according to a command from the control device, a rotary rack with an empty address is selected from the designated rotary racks 11+Iz, ---In, rotated, and stopped at the warehousing gate position. Then, the lifting stop sensor 8 causes the warehousing lifter to stop at the designated warehousing gate position, and the container 2 is transferred to the empty address position and warehoved.

Furthermore, while a container is being transferred from the warehousing lifter to the rotary rack, it is of course possible to transfer another container to another warehousing lifter.

〔Effect of the invention〕

As explained above, the present invention has a plurality of lids attached to each of the storage section and the storage section, thereby reducing the man-hours for loading and unloading the warehouse, and quickly and without delay in responding to requests from the assembly department. It has excellent practical effects.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of a warehouse delivery section according to an embodiment of the present invention, FIG. 2 is a perspective view of a rotary type warehouse, and FIG. 3 is a perspective view of a conventional warehouse delivery section. In the figure, 15,1□, -In is the opening, -tally rack, 2 is the container, 3 is the storage section, 4 is the storage section, 3A is the storage lifter, 3B is the storage conveyor, 5 is the storage conveyor, 6.15 is a lifter for delivery, 8 is a lift stop sensor, 9 is a delivery gate, IO is a pusher, 16 is a tilting arm, 17 is a lifter guide, 18 is a container delivery mechanism, 19 is a delivery part sensor, 20 is a lifter directional sensor, 21 indicates rack right row sensors. Figure 1

Claims (1)

[Claims] In a warehouse system in which rotating rotary racks are installed in multiple stages to hold a large number of containers in stock at predetermined positions, there is a storage section equipped with a plurality of storage lifters that rotate up and down as desired, and and an unloading section equipped with a plurality of rotatable unloading lifters, and the incoming lifter loaded with containers stops at the incoming gate corresponding to the nearest empty address position of the rotary rack and unloads the containers. The specified container is transferred onto a rotary rack and entered the warehouse, and with the rotary rack stopped, the nearest unloading lifter moves to the position corresponding to the unloading gate so that the specified container is located at the unloading gate. 1. A loading/unloading mechanism for a rotary type warehouse, characterized in that the storage/unloading mechanism for a rotary type warehouse is configured to stop, transfer the designated container to the unloading lifter, and unload the container.