The present invention is directed to item labeling architecture, and in particular, to a high-rate, wide range of materials to be handled (MTBH) label applicator architecture.
Conventional item labeling techniques typically include a variety of conveyors or conveyor modules, with various sizes and arrangements available based on the size and characteristics of the MTBH for a particular label applicator. MTBH may include parcels, envelopes, boxes, cartons, items, object, articles, etc. Such conveyors typically utilize large 480 VAC motors and drive belts to drive conveyor sections, which may include a skewed induction bed to align the articles and/or to gap or pitch the articles to a desired distance between one another. Alignment, gapping, and/or pitching may be performed manually by an operator. After gapping, the articles are scanned to identify the article. This identification information is sent to a host or system controller which responds by sending a print file for the article to a label printer and applicator. Common labeling systems transfer label print files to the label printer via a file transfer protocol (FTP). The printer and applicator receives the print file, and once the article is present, prints the label and applies the printed label to the present article. After receiving the printed label, the article continues down a conveyor surface for verification where the printed label is inspected to ensure that the printed label is readable and contains the correct information for the article upon which it is affixed. An article that passes verification continues on for further processing (e.g., a downstream conveyor to shipping or loading dock), while an article that fails verification is typically manually removed by an operator from the conveyor system.
The present invention provides a high-rate, wide range of material to be handled (MTBH), and robust label applicator architecture and control method, which includes a label, print, and apply (LPA) system, apparatus, or module which utilizes a less-expensive and more robust hardware and software architecture than conventional systems by improving accuracy of article labeling, improved overall uptime, and improved labeling rate for a significantly wide MTBH range of articles, items, parcels, packages, cartons, boxes, envelopes, etc. The labeling rate and continuous operation of the LPA is improved by dynamically adjusting the gap and pitch between articles as they enter an auto sort and label system. The LPA may be provided in the form of conventional or known LPA systems, such as those configured for contactless label application and utilizing servo motors.
According to an aspect of the present invention, an exemplary auto sort and label (ASL) system includes a conveyor, a controller, a sensor array, and a label, print, and apply (LPA) system, apparatus, or module. The conveyor conveys articles through the ASL system. The sensor array is positioned along the conveyor and IDs an article and determines dimensions of the article. The controller receives sensor data from the sensor array. The LPA is positioned alongside and in-line with the conveyor and prints labels and applies them to articles. The controller selects print strings (as opposed to print files) defined by the ID of the article determined from the sensor data. The LPA prints the label as defined by the print string. The controller controls the conveyor such that a gap/pitch between a first article and a second article is adjusted. The controller verifies placement and contents of the label upon the article as defined by sensor data and accepts or rejects the labeled article for further handling based on the verification.
In an aspect of the present invention, the at least one sensor comprises a first sensor array configured to determine an identity of each article of the plurality of articles. The at least one sensor comprises a second sensor array configured to verify the labeled article. In another aspect of the present invention, the first sensor array and the second sensor array are part of a single sensor array.
In a further aspect of the present invention, the conveyor comprises a plurality of individually addressable motorized driven rollers (MDR). The MDRs are controlled by the controller.
In yet another aspect of the present invention, the at least one sensor array comprises a plurality of cameras, a plurality of barcode scanners, and/or a plurality of photo eyes. The sensor array may be configured and function similar to systems and methods described in commonly owned and assigned U.S. Patent Application Publication No. 2020/0095064A1, published on Mar. 26, 2020, the disclosure of which is hereby incorporated by reference herein in its entirety.
In an aspect of the present invention, the LPA comprises a label applicator configured to apply the label to an article by releasing a measured quantity of air to blow the label onto the article. The controller and/or the LPA is configured to determine whether a current print string matches the next article. The label applicator is configured to blow off the label into the air, such as when the print string does not match the next article, or if there is insufficient time to print and apply a label to a subsequent article due to insufficient minimum pitch/gap requirement.
In another aspect of the present invention, the controller is configured to direct the conveyor to allow a verified article of the plurality of articles to proceed downstream to further handling. The controller is configured to direct the conveyor to kick an unverified article of the plurality of articles off the conveyor, such onto a diagonal conveyor or chute or into a holding bin away from the main conveyor line for further handling.
In a further aspect of the present invention, the LPA is configured to handle and apply labels onto a wide range of material to be handled (MTBH), which comprises articles of 3 mm thick padded envelopes that weigh under 1 pound, up to packages 25 inches tall that weight up to 60 pounds.
These and other objects, advantages, purposes and features of this invention will become apparent upon review of the following specification in conjunction with the drawings.
The present invention will now be described with reference to the accompanying figures, wherein the numbered elements in the following written description correspond to like-numbered elements in the figures.
Referring now to the drawings and the illustrative embodiment depicted therein, exemplary auto sort and label (“ASL”) systems 100 (
The LPA 106 receives the print data string from the system controller 150, and using the encoded print data, prints a label for the article. With the label printed, the LPA 106 is ready to apply the label to the article once the article is moved by the conveyor to the LPA 106. Dynamic gapping and pitching ensures the label is ready prior to the article arriving at the LPA 106 such that the label may be applied seamlessly as the article passes through the LPA 106, preferably without the article stopping or slowing down. In an aspect of the present embodiment, the LPA 106 applies the label to the article by pre-positioning the applicator slightly above the article then blowing the label onto the article once the article has arrived at the point of application at the LPA 106. After application of the label onto the article, the article is conveyed by the conveyor to a verification bed 107 where another set of cameras and/or barcode scanners 122 scan the applied label(s) on the article as well as the original article identifier. The system controller 150 uses the cameras and/or barcode scanners 122 to confirm that the applied label is printed legibly, includes the correct information, and confirms that the printed label is the correct label for the article upon which it is affixed using the original article identifier barcode and the tracking of the article to the application location. The cameras and/or barcode scanners 121 and 122 may be configured and function similar to systems and methods described in previously mentioned U.S. Patent Application Publication No. 2020/0095064A1.
The verification bed 107 and an accompanying kickoff conveyor are capable of automatically removing articles without labels or misapplied labels without stopping the conveyor line and without the need for manual intervention from an operator. In an optional embodiment, if the system controller 150 successfully verifies the article's label, a green beacon illuminates to indicate that the article will be discharged from the verification bed 107 to be received by a downstream conveyor 116, such as for delivery to a loading dock or shipping area, for example. If the article label is not verified successfully, a red beacon illuminates to indicate that the article will be removed from the conveyor and pushed into a rejection hamper or bin 112 or kicked off onto the adjacent kickoff conveyor for further correction. Alternatively, the system 100 may be configured such that an operator may manually remove articles upon indication from the red beacon.
Similar to the ASL system 100, the alternative ASL system 200 includes an induction bed 202 with at least a portion having an arrangement of skewed rollers 201a (which may be provided in the form of MDR 201) to shift, reposition, or realign the articles such that they align to either the right- or left-hand side of the conveyor depending on the skew arrangement (in the illustrative embodiment of
Using the MDR sets, the article's position with respect to the previous or immediately preceding article on the conveyor is adjusted by the controller 230 for a desired gapping and/or pitch. As discussed previously, a gapping is a physical space or distance between two articles on the conveyor surface, while pitch is the physical space or distance between the leading edges of two articles on the conveyor surface (or alternatively the pitch may be measured as the distance between the trailing edges of two articles if that is a more useful data point). The selected or predefined gap and/or pitch distancing optimizes a ratio between the gap and/or pitch based on the previously scanned articles. That is, the controller 230 dynamically adjusts the gapping and/or pitch between articles based upon the dimensions of the previously scanned articles. The controller 230 is configured to dynamically correct non-ideal or incorrect gapping/pitching between articles prior to the article entering the scanning bed 204 and/or LPA bed 205 and LPA 208. The controller 230 controls the MDR rollers to individually adjust their rotation rate to correct or adjust the gapping/pitch between the articles and thereby increase or decrease the gap and/or increase or decrease the pitch. Such adjustment can be used to match the previous gap/pitch between previous upstream articles to create a uniform flow of articles through the scanning bed 204 and LPA bed 205.
The ASL system 200 includes a scanning bed 204 after the gapping/pitching bed 203 (
Leaving the scanning bed 204, the articles move along the conveyor to enter an LPA applicator bed 205 of the ASL system 200. As illustrated in
The articles handled by the system 200 (and system 100 as well) may vary significantly, such as from padded envelopes to large boxes. For example, in an aspect of the present embodiment, the MTBH includes articles of 3 mm thick envelopes weighing less than a pound, up to 25-inch-tall packages weighing up to 60 pounds. Note that many articles may have a non-uniform profile, such as polybags or non-uniform polygonal cartons. Product inside the polybags may create an inconsistent profile of the polybag which may result in difficulties in article tracking, scanning, label application and sortation. The exemplary embodiments include sufficient scanning (via the sensor array 220) and article handling (via the MDAs of the gapping/pitching bed 203) to handle a wide variety of articles. The controller 230 is configured to dynamically correct non-ideal or incorrect gapping/pitching between articles while the article is present in either the gapping bed 203, scanning bed 204, and/or LPA bed 205/LPA 208, which further provides dynamic control of the system 200 which may reduce the need to stop the ASL system 200 to correct for mislabeled, unlabeled, or out of sequence articles.
In an aspect of the present embodiment, after printing the label, the LPA 208 utilizes a “blow on” label applicator, which blows the printed label onto the article. This is opposed to rolling, pressing, or other physical interactions with the articles, such that during label placement, the LPA 208 will not crush or substantially contact the article. The label applicator of the LPA 208 may be provided at the end of an articulating robotic arm or manipulator that is moveable in multiple directions and coordinates. Preferably, the LPA 208 arm is prepositioned prior to label application based on the article height to maximize LPA 208 throughput. If the LPA 208 (and/or the controller 230) determines that an already printed label is out of sequence with the article approaching the LPA bed 205 or that an article has entered the LPA applicator bed 205 with insufficient gap/pitch to adequately apply its label, the LPA 208 is configured to purge the already printed label. As noted herein, the LPA 208 utilizes a blow on label applicator. Thus, when a printed label is to be purged, the blow on label applicator will be instructed to physically blow the label into the air to waste (i.e. blow the label away from the conveyer system). Note that during the brief period of time when the LPA 208 is blowing off an incorrectly printed label, the ASL system 200 may briefly pause or at least slow down induction of new articles onto scanning bed 204, but not significantly interrupt the flow of articles in the system 200. Thus, the ASL system 200 allows for automatic recovery in the event the LPA 208 incorrectly prints a label without requiring line stoppage. An exemplary LPA 208 may include a ZE511 printer marketed under the mark ZEBRA® by Zebra Technologies Corporation of Lincolnshire, Illinois, and an LA-6000 variable height printer applicator from WEBER® Packaging Solutions of Arlington Heights, Illinois, or similar LPA configurations.
As illustrated in
It is contemplated that the sensor arrays 220 and 222 are considered to comprise the cameras and/or barcode scanners 224 and 226. However, it will be appreciated that the sensors arrays 220 and 222 may be utilized independent of the cameras and/or barcode scanners 224 and 226. It will also be appreciated that only one type of sensor, in the form of either photoeyes, cameras, or code scanners, may be utilized without affecting the function of the system 200. The sensor arrays 220 and 222 and cameras and/or barcode scanners 224 and 226 may be configured and function similar to systems and methods described in previously mentioned U.S. Patent Application Publication No. 2020/0095064A1.
A next section of the conveyor of the ASL system 200 includes a kickout bed 207 which is configured to “kick out” or reject articles from the conveyor surface by kicking them off the conveyor surface of the kickout bed 207 (such as into a removable bin 210 alongside the bed 207 or to another discharge conveyor adjacent the bed 207) to be retained for or redirected to quality assurance (QA) operators, which can manually correct or apply replacement labels. Thus, the kickout bed 207 allows for automatic recovery in the event the LPA 208 applies a label out of sequence, or prints a label that is not sufficiently readable, or when an article is not sufficiently gapped/pitched when it enters the LPA, such that there is no significant line stoppage. In the event that a label has been improperly printed (e.g. out of sequence) and detected before application to an article, the label is blown off into the air. At this time the article (without a label) is rejected while passing through the verification bed 206 and is kicked out by the kickout bed 207 for later label placement. Optionally, the systems 200 may be capable of recovering sufficiently quickly such that a new, correct label may be readily printed and applied to the article while it is still present at the LPA bed 205 (such as in times of low throughput demand). When an article has passed verification, the article will pass the kickout bed 207 and continue to a downstream process, such as into or onto a shipping or loading dock area 212 via a transfer conveyor system, for example (see
As illustrated in
As illustrated in
It will be appreciated that the features, functions, and benefits of the exemplary ASL systems 100, 200, and method 300 may be adapted or applied for use with other LPAs and ASL systems.
Thus, exemplary ASL systems 100 and 200 provide for efficient, uniform, and timely labeling of articles through the use of dynamic gap and/or pitch adjustment (via utilization and dynamic control of individually controlled as opposed to less responsive and configurable belt conveyors) to maximize article handling rates through the systems. The ASL systems 100 and 200 include an automatic recovery for errors in the system to minimize or eliminate stoppages and slowdowns of the conveyor system that negatively affect throughput. Such errors include an out-of-sequence label application, out of sequence, mis-oriented, mis-gapped and/or mis-pitched articles, and/or an inadequately printed or applied label. Through the use of dynamic gap and/or pitch adjustment and multi-variant matching algorithms the ASL systems 100 and 200 is well-suited for automatically recovering from an insufficient gap and/or pitch errors, efficiently marrying label printing and application with article identification and transport to, through, and past the label applicator, and seamlessly removing articles without labels or mis-applied labels.
Changes and modifications in the specifically described embodiments can be carried out without departing from the principles of the present invention, which is intended to be limited only by the scope of the appended claims, as interpreted according to the principles of patent law including the doctrine of equivalents.
This present invention claims priority of U.S. provisional application Ser. No. 63/414,676, filed on Oct. 10, 2022, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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63414676 | Oct 2022 | US |