1. Field of the Invention
This invention relates to a case/bulk layer formation table and process including a multi-axis programmable, robot.
2. Description of Related Prior Art
Conveyors are commonly used in manufacturing and processing operations to move articles or goods from one operation to another. For many types of operation it is advantageous to have the articles grouped for batch processing. Such typical batch-processing operations include applying labels to bottles or cans or other types of containers, packing bottles, cans or boxes into crates, or filling containers with liquid or semi-liquid material. A number of devices or systems are known that group articles for batch processing. Many of the systems known in the prior art use a system that run alongside one side or both sides of the conveyor transporting the articles to be processed.
The prior art devices have several disadvantages. They are cumbersome and require space to each side of the conveyor and above the conveyor. They also are material-intensive and thus, expensive. Further they also are power-intensive because they run continuously. Furthermore, these devices do not change configuration of the number of articles abreast, i.e., they do not convert a single or double file feed of articles to multiple articles abreast, but merely create a distance between one group of rows of articles and a following group.
Typically prior art transfer is carried out with an overhead frame. The prior art unit uses a complicated system including assemblies extending transversely of the apparatus in and being vertically movable toward and away from one another in a vertical transverse plan. Upper and lower crankshafts are intermittently driven through a one-revolution cycle often by a chain and sprocket drive mechanism. After sweeping or pushing the load, the device must be raised, moved back to its starting point and lowered on the next load.
In summary, the invention is an apparatus for transferring articles. The apparatus includes a layer formation table. The apparatus also includes means for supplying articles to the layer formation table. At least one row of the articles is formed at a first end of the layer formation table. The apparatus also includes a programmable robot including an end of arm tool for transferring the at least one row of the articles towards a second end of the layer formation table. The programmable robot is configured to form a plurality of rows of articles on the layer formation table. Each of the rows comprises a plurality of articles in side by side contact creating a void between adjacent articles in each of the rows. The programmable robot is configured to nest the articles of one of the rows in the voids of an adjacent row. The end of arm tool includes a multiplicity of guides which form lanes. The rows of articles fill the lanes. The end of arm tool includes clamping tools which lock the individual rows of articles between the guides.
A case/bulk layer formation table is disclosed including a multi-axis programmable robot. In one embodiment, an EOAT on the cantilevered arm of the robot can be designed to transfer rows of bulk product (such as, by way of example and not limitation, bottles) or cases.
A process for transferring articles can comprise the steps of: providing a layer formation table; supply articles to the layer formation table; forming at least one row of the articles at a first end of the table; and providing a programmable robot including an EOAT for transferring the row of the articles towards a second end of the table. The process can further comprise the step of configuring the robot to build a tier of products on the layer formation table.
In one embodiment, robot 18 picks up case 36 from tier case station 16 and places them in load building area 26. The two robot system provides flexibility in that the line can still run if one side is down for repair, maintenance or product set up. In this embodiment, robot 28 picks up top cap 43 instead of top frame 42. Pallets, tiers, tier sheets, top frames and top caps often are referred to as dunnage.
Bulk product feeder 14 typically comprises a multiplicity of parallel conveyor belts 46 which carry rows of bulk product 34 (bottles). Frame 48 support belts 46. The rows are fed to the tier staging area 24. Tier staging area 24 typically includes a conveyor which comprises frames and supporting feed belts. Usually tier staging area 24 is at the end of bulk product feeder 14.
Tier case station 16 typically comprises a multiplicity of parallel conveyor belts 56 which carry cases 36 of product 34 (bottles). Frame 58 support belts 56. The cases are fed to load build area 26 for pick up by robot 18.
Cases as used herein may vary widely. Typically cases means a case of 24 beer bottles. Cases may include a 6 pack, 12 pack, 18 pack, 30 pack and the like. The case may be corrugated cases, chip board cases or film wrapped bundles of product. A typical film wrapped case is a film wrapped package of six or twelve rolls of paper towels.
Tier sheet station 22 comprises conveyor which includes a frame supporting rollers. Tier sheet station 22 is next to pallet station 20 and also parallel to load build area 26. Robot 28 picks up pallet 38 from pallet station 20 and locates it at load build area 26. This is followed sequentially by alternating layers of tier sheet 40 and tier 32 (cases 36). In one embodiment where no pallet 38 is employed, the first layer is tier sheet 40.
The rows of product 34 form tier 32 on a conveyor. The conveyor then transports tier 32 to tier staging area 24. As will be shown later, tier 32 is located in load build area 26 by robot 18. Dunnage supply line 19 provides pallets 38 to pallet station 20 and top frames 42 to top frame station 28. Line 19 feeds to stations 20 and 28. Pushers such as chain transfers 54 and 56 move pallets 38 and top frames 42 to stations 20 and 28, respectively.
Pallet station 20 comprises conveyors which includes frames supporting a multiplicity of rollers. Pallet station 20 usually is near load build area 26. Tier sheet station 22 comprises conveyors, frames and a multiplicity of rollers.
Dunnage line 19 comprises conveyors which includes frames supporting a multiplicity of rollers.
Top frame station 28 comprises conveyors which includes a frame supporting a multiplicity of rollers.
When the tier comprises cases 36, top frame station 28 feeds top caps 43 instead of top frames 42.
Load conveyor 50 removes load 12 from load building area 26. Conveyor 50 comprises frames and rollers. Typically, conveyor 50 transfers load 12 strapping area 52.
PLCs in a control panel controls system 10, the load and dunnage conveying system. The PLCs in the control panel controls the tier building system. PLCs interface with the control, which controls robot 18 and robot 28. PLCs also interface with other PLCs and can be the main control for system 10. Power control panels are wired to their respective drives and sensors and actuators.
A distal end of cantilevered arm 100 carries mounting plate 104. Plate 104 attaches to arm 100 with conventional fasteners and effector 102 attaches to plate 104 with similar mechanical fasteners.
Robot 18 is a programmable multi-axis robot. Previously-discussed controllers controls robot 18. Typically the multi-axis robot 18 has five axes of motion. In another embodiment arm 100 may be a Cartesian arm.
In another embodiment EOAT 120 acts as a pusher and pushes cases of bulk product in rows 130 down conveyor 132 to station 134. In this embodiment, the EOAT is a pusher that pushes the cases down the conveyor instead of sweeping.
The above detailed description of the present invention is given for explanatory purposes. It will be apparent to those skilled in the art that numerous changes and modifications can be made without departing from the scope of the invention. Accordingly, the whole of the foregoing description is to be construed in an illustrative and not a limitative sense, the scope of the invention being defined solely by the appended claims.
This application is a continuation of U.S. patent application Ser. No. 12/011,890, for a LAYER FORMATION TABLE AND PROCESS, currently pending and filed Jan. 30, 2008, which further claims the benefit of United States Provisional Patent Application Serial No. 60/997,087, filed on Oct. 1, 2007, and United States Provisional Patent Application Serial No. 60/898,499, filed on Jan. 31, 2007, all of these applications are hereby incorporated by reference in their entireties.
Number | Date | Country | |
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60997087 | Oct 2007 | US | |
60898499 | Jan 2007 | US |
Number | Date | Country | |
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Parent | 12011890 | Jan 2008 | US |
Child | 14294371 | US |