Patent Application
20250033879
The present invention falls within the field of the production of automated systems for the storage of items on pallets in an automated warehouse.
In particular, the present invention relates to a load handling device, in particular for handling pallets containing articles, for automated warehouses.
Automated warehouses structured to allow the automatic storage of pallets are known in the art.
From a design point of view, these warehouses normally employ load-bearing structures comprising a structure with shoulders and uprights that defines a plurality of storage aisles of variable dimensions as a function of the expected loads. The pallets are arranged and picked up along/from such aisles through automated devices, called satellites or shuttles. In practice, these devices deposit, automatically and in series, a plurality of pallets on support guides arranged along the storage aisle. In more detail, this deposit normally takes place starting from one end of an aisle or in any case from the first free position identified within the aisle itself.
In order to perform the operations for which it is intended, the satellite normally comprises a frame provided with a plurality of wheels so as to allow the satellite to be translated along the storage aisle.
These wheels are actuated by suitable handling means which generally consist of electric motors, which are operatively controlled by command and control means and which are powered by suitable power supply means, such as batteries.
The satellite further comprises a platform suitable for providing a support surface for the pallet, as well as position detection means suitable for determining the position of the satellite in one or more points of the aisle, or means for detecting the position in a continuous manner, for example by means of laser position detection systems.
The devices of the prior art, made up to now, provide for the frame on which the wheels are hinged and which supports the motors and the control unit to be designed in such a way as to support the heavy loads, both static and dynamic, and the fatigue loads that the satellite encounters during its operation. Given the extreme working conditions, in order to guarantee adequate strength and reliability, all the frames are therefore designed in single pieces or in heavy iron plates welded together and painted to guarantee resistance to corrosion even in aggressive environments, such as refrigerating rooms.
However, the aforesaid peculiarities of the prior art devices involve numerous drawbacks: a high weight of the device, large dimensions, construction complexity, the need for large storage volumes of the frames during construction and limited ease and efficiency in transporting the devices from the production site to the installation site.
The need to remedy the aforementioned drawbacks relating to the prior art is therefore strongly felt.
In particular, an object of the present invention is to provide a load handling device which is at the same time robust and easy to manufacture, and which allows improved efficiency and ease of transport.
This object is achieved by a load handling device according to the accompanying independent claims. The dependent claims describe preferred embodiments.
The features and advantages of the load handling device according to the present invention will appear more clearly from the following description, made by way of an indicative and non-limiting example according to the accompanying figures, wherein:
Despite the present invention is described below with reference to preferred embodiments shown in the drawings, the present invention is not limited to the embodiments described below and shown in the drawings. On the contrary, the described and represented embodiments clarify some aspects of the present invention.
The present invention has proved to be particularly advantageous with reference to the implementation of a load handling device suitable for moving within a warehouse in an autonomous/semi-autonomous and preferably self-powered manner, as better described hereinafter.
However, it should be pointed out that the present invention is not limited to the implementation of an autonomous and self-powered device. On the contrary, the present invention finds convenient application in all cases involving the use of a device which moves within a suitably powered warehouse, for example a power supply system on fixed guides on which the device rests.
The warehouse 200 shown in the figures by way of example has a simple layout and preferably comprises storage aisles 11, 21, 31 arranged laterally with respect to a central aisle 51.
The warehouse 200 also preferably comprises a loading/unloading station 18 for the loads, that is an area on which a load 100 which must be stored in a predetermined compartment of the warehouse 200 is placed, or an area on which a load taken from a compartment of warehouse 200 is placed.
The handling of a load 100 within the warehouse 200 is advantageously carried out by the load handling device 1 according to the invention.
The handling of the load in the warehouse 200 consists, preferably, in handling said load from the loading/unloading station 18 towards and in the aisles 11, 21, 31.
The load handling device 1 according to the invention preferably allows the handling of loads of large dimensions and weights, such as pallets, but other types of articles are not excluded.
The load handling device 1 according to the invention is therefore, in particular, suitable for handling pallets containing articles, for automatically storing the load 100 in a warehouse 200. The load handling device 1 comprises a base frame 6 onto which wheels 10A, 10B, 10C, 10D are rotatably connected, which wheels are suitable for allowing the translation of the load handling device 1 along a storage aisle 11, 21, 31 of the warehouse 200. This base frame 6 therefore defines an inner compartment 67, preferably having a box shape, and extending in height to a much lesser extent than the other two dimensions of width and length.
The load handling device 1 also comprises first handling means 61 arranged inside said base frame 6, in the inner compartment 67, and operatively connected to one or more of said wheels 10B, 10D for achieving the translation of the load handling device 1.
The load handling device 1 comprises one or more operational portions 7 defining a temporary support plane PA for the load 100, and second handling means 62 arranged inside the base frame 6 and operatively connected to such operational portions 7 for moving them with respect to the frame base 6 between a base position and a lifting position spaced vertically, that is in height, with respect to the base position.
In one embodiment, the one or more operational portions 7 comprise a pair of support bars 7a, 7b.
Preferably, first handling means 61 comprise one or more electric motors, associated with one or two of the wheels 10B, 10D. Of the total number of wheels 10A, 10B, 10C, 10D it is preferable that only some of them are driving wheels and that the remaining ones are idlers.
In a preferred embodiment, the device 1 comprises main power supply means 68, or primary power supply means, mounted on board the device itself so as to make the device autonomous and self-powered.
In a preferred embodiment, the main power supply means 68 comprise supercapacitors and/or batteries, for example lithium batteries, positioned in the base frame 6.
In an alternative embodiment, a power supply system for the motors may be provided by means of power bars located on the floor along the aisle and a brush on board the device which, placed in continuous contact with the power bar, transfers the electric power supply energy for the parts on board the device.
According to an embodiment, a central control unit 800 is integrally associated with the base frame 6 of the device 1. The central unit 800 controls all the moving parts of the device 1 and the communication with the sensors. Preferably, the central unit 800 also communicates with a warehouse management unit, on which a warehouse software manages the operation of the warehouse 200 and in particular the movements of the device 20 within the warehouse 10. The communication between the central unit 800 and the warehouse management unit is preferably wireless communication.
The central unit 800 is powered by said main electric power supply means 68.
According to the invention, the base frame 6 of the device 1 consists of sheet elements 150, 160, 170, 180, 190 made of stainless steel joined together by gluing and by means of repositionable fixing means, e.g. screw, rivet or expansion means. This allows for easy construction while ensuring adequate strength and reduced storage space.
According to an embodiment, the sheet elements comprise a bottom sheet 150, a right side sheet 160, a left side sheet 170, a head sheet 180, and a tail sheet 190. Preferably, the base frame is made only from the joining of the bottom sheet 150, the right side sheet 160, the left side sheet 170, the head sheet 180 and the tail sheet 190, without other sheets. It is clear that the load handling device 1, on the other hand, may also comprise a lid and other accessories.
Preferably, the joining of the bottom sheet 150, the right side sheet 160, the left side sheet 170, the head sheet 180 and the tail sheet 190 defines a box shape which contains the inner compartment 67.
Preferably, the right side sheet 160, the left side sheet 170, the head sheet 180 and the tail sheet 190 are all joined to the bottom sheet 150 by gluing, preferably by means of an epoxy glue, which ensures ease of installation and at the same time ensures a mechanical seal even in low temperature environments, such as refrigerating rooms.
According to an embodiment, one or more stiffening rods 151, 152 are fixed to the bottom sheet 150 on a bottom sheet outer side 150′, opposite to a bottom sheet inner side 150″. The bottom sheet inner side 150″ is therefore the side that faces towards the inner compartment 67 of the device 1, whereas the bottom sheet outer side 150′ does not face towards the inner compartment 67.
The stiffening rod(s) 151, 152 contribute(s) to making the bottom sheet adequate to support the mechanical stresses to which it is subjected.
Equivalently, the stiffening rods 151, 152 may be replaced by stiffening ribs or by a reinforced section of the bottom sheet 150, for example having an alternation of promontories and valleys, preferably on the bottom sheet outer side 150′.
In general, in the present disclosure, “outer” or “externally” means any element that is located outside the inner compartment 67.
Preferably, the stiffening rods 151, 152 are mutually spaced apart and preferably arranged substantially along one main dimension of the load handling device 1, for example along the entire length of the device 1.
According to an embodiment, the sheet elements 150, 160, 170, 180, 190 comprise guide portions 152, 154, 162, 174 mutually interlocked to ensure unambiguous coupling between the sheet elements and the correct centering. This is particularly effective in the step of assembling and gluing the sheet elements.
Preferably, in an advantageous manner, the load handling device 1 is not painted at least externally or totally, that is it is totally unpainted both internally and externally.
Furthermore, preferably, the stainless steel of the sheet elements is an austenitic steel X5 CrNi 18-10, according to the standard EN 10088-3:2005.
According to an embodiment, the load handling device 1 also comprises a measuring wheel 8, rotatable about a wheel rotation axis X. The measuring wheel 8 is connected to the base frame 6 in a translatable manner along a wheel translation direction incident to the support plane PA or in a rotatable manner about a wheel rotation axis Z parallel to the support plane PA (as for example shown in
Furthermore, the load handling device 1 also comprises a device for detecting the angular position of the measuring wheel 8, for example an electronic encoder (such as an optical position encoder).
In this embodiment, an elastic element 81 is preferably provided, suitable for being elastically deformed during translation of the measuring wheel 8 along the wheel translation direction or during rotation of the measuring wheel 8 about the wheel rotation axis Z, so that the measuring wheel is always in contact with the rails of the warehouse while in operation, while remaining unloaded by the weight of the load 100 (contrary to what happens to the other wheels 10A, 10B, 10C, 10D of the device).
Innovatively, the present invention successfully overcomes the cited drawbacks with respect to the devices of the prior art.
In particular, by virtue of the presence of the base frame assembled by gluing and fixing stainless steel sheet elements with repositionable elements, high reliability and durability over time are guaranteed in synergy with ease of construction and smaller storage and shipping dimensions.
Contrary to the devices of the prior art, in fact, the stainless steel elements do not require painting, greatly reducing the production procedures and therefore the demand for resources. Moreover, in a synergistic manner, a total absence of any risk of corrosion, which is typical of devices of the prior art, is guaranteed, above all in extreme environments, such as refrigerating rooms. This greatly reduces maintenance demands.
Advantageously, the synergistic union between stainless steel elements that do not require painting and the assembly by gluing and repositionable fixing elements allows the frame to be made with sheets with reduced overall dimensions, while guaranteeing improved resistance performance and mechanical reliability.
In particular, the step of storage and shipping of the disassembled sheet elements is enormously more efficient than having to ship and/or store entire heavy, cumbersome and also painted base frames, as happens instead for devices of the prior art.
Furthermore, the total absence of welding in the device according to the present invention avoids the loss of abutments for the assembly of the frame, which instead frequently occurs with the frames of the prior art.
Furthermore, in an advantageous manner, the measuring wheel which is translatable or rotatable with respect to the support plane allows such wheel to always be floating and under pressure in contact with the aisle rails. In this way, contrary to what happens to the other wheels of the device, the measuring wheel does not undergo any elastic deformation due to the weight of the load and, therefore, a high measurement accuracy is guaranteed, irrespective of the weight and type of load supported by the handling device 1.
In order to meet specific needs, a person skilled in the art may make several changes to the embodiments of this invention or substitutions of elements with other functionally equivalent ones.
These variants are also contained within the scope of protection as defined by the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102021000029291 | Nov 2021 | IT | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/IB2022/061077 | 11/17/2022 | WO |
