LABEL PRINTER APPLICATOR SYSTEM

Abstract

A printer system is disclosed comprising: a first print and apply device configured to print or encode a label and apply one or more label to one or more packages, wherein the device has a printer/encoder portion and an applicator portion; a first motor to move the print and apply device in an X-direction; a second motor to move the print and apply device in a Y-direction; third motor to move the print and apply device in a Z-direction; a second print and apply device configured to print or encode a second label and apply the one or more label to the one or more package, wherein the device has a printer/encoder portion and an applicator portion; a first motor to move the print and apply device in an X-direction; a second motor to move the print and apply device in a Y-direction; a third motor to move the print and apply device in a Z-direction; a switching device that delivers the one or more packages to the first or second print and apply device on request; a controller coupled to the printer system and having a single interface configured to receive a single data stream comprising label data and positioning data from a single data stream; and a command parser configured to receive the single data stream and parse label data to the printer/encoder portion and positioning data to the applicator portion, In one embodiment, the switching device is a robotic arm. In one embodiment, the switching device is a conveyor belt system. In one embodiment, the switch device is requested to deliver to the first or second print and apply device when either the first or second print and apply device is low on ink.

Claims

1. A printer system, comprising: a first print and apply device configured to print or encode a label and apply one or more label to one or more packages, wherein the device has a printer/encoder portion and an applicator portion; a first motor to move the print and apply device in an X-direction; a second motor to move the print and apply device in a Y-direction; a third motor to move the print and apply device in a Z-direction; a second print and apply device configured to print or encode a second label and apply said one or more label to said one or more package, wherein the device has a printer/encoder portion and an applicator portion; a first motor to move the print and apply device in an X-direction; a second motor to move the print and apply device in a Y-direction; a third motor to move the print and apply device in a Z-direction; a switching device that delivers said one or more packages to said first or second print and apply device on request; a controller coupled to said printer system and having a single interface configured to receive a single data stream comprising label data and positioning data from a single data stream; and a command parser configured to receive the single data stream and parse label data to the printer/encoder portion and positioning data to the applicator portion.

2. The printer system of claim 1 wherein said switching device is a robotic arm.

3. The printer system of claim wherein said switching device is a conveyor belt system.

4. The printer system of claim 1 wherein said switch device is requested to deliver to said first or second print and apply device when either said first or second print and apply device is low on ink.

5. A printer system, comprising: a first print and apply device configured to print or encode one or more label and apply the label to one or more package; wherein said first print and apply device has a printer/encoder portion and an applicator portion; a first motor to move the print and apply device in an X-direction; a second motor to move the print and apply device in a Y-direction; a third motor to move the print and apply device in a Z-direction; a first supplemental motor to rotate the print and apply device along the X-axis; a second supplemental motor to rotate the print and apply device along the Y-axis; a third supplemental motor to rotate the print and apply device along the Z-axis; a camera for determining if said package is within field of view; a sensor for detecting skew angle of said package; a second print and apply device configured to print or encode said one or more label and apply the label to said one or more package; wherein said second print and apply device has a printer/encoder portion and an applicator portion; a first motor to move the print and apply device in an X-direction; a second motor to move the print and apply device in a Y-direction; a third motor to move the print and apply device in a Z-direction; a first supplemental motor to rotate the print and apply device along the X-axis; a second supplemental motor to rotate the print and apply device along the Y-axis; a third supplemental motor to rotate the print and apply device along the Z-axis; a camera for determining if said package is within field of view; a sensor for detecting skew angle of said package; a switching device that delivers said one or more packages to said first or second print and apply device on request; a controller coupled to said printer system and having a single interface configured to receive a single data stream comprising label data and positioning data from a single data stream; and a command parser configured to receive the single data stream and parse label data to the printer/encoder portion and positioning data to the applicator portion.

6. The printer system of claim 5 wherein said switching device is a robotic arm.

7. The printer system of claim 5 wherein said switching device is a conveyor belt system.

8. The printer system of claim 5 wherein said switching device is requested to deliver to said first or second print and apply device when either said first or second print and apply device is low on ink.

9. A printer system, comprising: a print and apply device configured to print or encode a label and apply the label to a package, wherein said device is comprised of a first printer/encoder portion and a second encoder portion and an applicator portion; a first motor to move said first print and apply device or said second print and apply device in an X-direction; a second motor to move said first print and apply device or said second print and apply device in a Y-direction; a third motor to move said first print and apply device or said second print and apply device in a Z-direction; a controller coupled to said printer system.

10. The printer system of claim 9 wherein said first motor to move said first print and apply device when said second print and apply device is out of ink.

11. The printer system of claim 9 wherein said second motor to move said first print and apply device when said second print and apply device is out of ink.

12. The printer system of claim 9 wherein said third motor to move said first print and apply device when said second print and apply device is out of ink.

13. The printer system of claim 9 wherein said controller is comprised of a single interface configured to receive a single data stream comprising label data and positioning data from a single data stream.

14. A printer system, comprising: a print and apply device configured to print or encode a label and apply the label to a package, wherein said device is comprised of a first printer/encoder portion and a second encoder portion and an applicator portion; a first motor to move said first print and apply device or said second print and apply device in an X-direction; a second motor to move said first print and apply device or said second print and apply device in a Y-direction; a third motor to move said first print and apply device or said second print and apply device in a Z-direction; a first supplemental motor to rotate the print and apply device along the X-axis; a second supplemental motor to rotate the print and apply device along the Y-axis; a third supplemental motor to rotate the print and apply device along the Z-axis; a camera for determining if said package is within field of view; a sensor for detecting skew angle of said package; a controller coupled to the print and apply device and having a single interface configured to receive a single data stream comprising label data and positioning data from a single data stream; and a command parser configured to receive the single data stream and parse label data to said first and second printer/encoder portion and positioning data to the applicator portion.

15. The printer system of claim 14 wherein said first motor to move said first print and apply device when said second print and apply device is out of ink.

16. The printer system of claim 14 wherein said second motor to move said first print and apply device when said second print and apply device is out of ink.

17. The printer system of claim 14 wherein said third motor to move said first print and apply device when said second print and apply device is out of ink.

18. The printer system of claim 14 wherein said controller is comprised of a single interface configured to receive a single data stream comprising label data and positioning data from a single data stream.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] FIG. 1 shows a diagram of a printer system for applying labels according to one embodiment;

[0015] FIG. 2 is a block diagram of a portion of the printer system of FIG. 1 according to one embodiment;

[0016] FIG. 3 shows an example command for use with the printer system of FIG. 1; and

[0017] FIG. 4 is a flow chart showing a process for applying a label anywhere on a package, according to one embodiment.

[0018] FIG. 5 illustrates the flow diagram for one implementation of the methods of accommodating skewed boxes used with the printer system.

[0019] FIG. 6 is a perspective view of the printer system using an angle image capture device and an auxiliary digital image sensor for determining document skew.

[0020] FIG. 7 shows another embodiment of the present invention.

[0021] FIG. 8a shows another embodiment of the present invention.

[0022] FIG. 8b shows another embodiment of the present invention.

[0023] FIG. 9a shows another embodiment of the present invention.

[0024] FIG. 9b shows another embodiment of the present invention.

[0025] Use of the same or similar reference numbers in different figures indicates same or like elements.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[0026] FIG. 1 shows a block diagram of a printer system 100 for applying labels to packages, according to one embodiment. System 100 includes a print and apply device or machine 102, which can receive information via a data stream from a host computer (not shown) that includes a host application, typically specific to the system through an electrical and software interface. Print and apply device 102 is commonly known and available, such as through the Printronix SLPA 8000 or Vanomation LPA 1000 models. In one embodiment, the host computer can be a conventional personal computer coupled to a local area network (LAN) or a PLC (Programmable Logic Controller connected thru serial port and/or Inputs/Outputs signals. The electrical interface can be any suitable communication means, such as, but not limited to, a serial or parallel physical link, an Ethernet connection, or a wireless link. The data stream contains various commands, such as line, box, font, and barcode commands, for printing lines, boxes, text, barcodes, and other images. The data stream is transmitted to the printer portion of print and apply machine 102 in specific languages to cause the printer to print an image on a label or other media.

[0027] Typically, each manufacturer uses a unique and specific language or software interface, such as PGL (Printronix Graphics Language used and supported by Printronix of Irvine, Calif.), ZPL (Zebra Programming Language used and supported by Zebra Technologies of Illinois), and IPL (Intermec Programming Language used and supported by Intermec of Washington). Other manufacturers with specific languages include TEC and Sato.

[0028] Print and apply machine 102 may include a printer data control section that receives the data stream and a printer engine control section for printing the label, as is known in the art. The printer engine control section manages the printer components (e.g., the print head, ribbon motors, platen motor and roller, sensors, etc.) to cause a printed image to be created on the label, based on the received image data.

[0029] Print and apply machine 102 is coupled to an X-motor 104, a Y-motor 106, and a Z-motor 108. X-motor enables print and apply machine 102 to move in the X-direction, as shown, such as by driving mechanisms or the machine itself. Similarly, Y-motor 106 and Z-motor 108 enable print and apply machine 102 to move in the Y-direction and Z-direction, respectively, as shown. With three degrees of freedom, printer system 100 is capable of applying a label 110, tag, or other article anywhere on a carton 112 or package, where carton 112 can be different sizes and heights. Details of an application process will be discussed below.

[0030] Print and apply machine 102 can include a thermal printer or any other suitable printer. The minter prints the optical information on labels as they pass through the print station. The labels may be in a roll and the roll unwound to expose each label to the print head for printing. Suitable printers may also include RFID devices that encode and/or write information onto an RFID tag or label. After the label is printed and/or encoded, an applicator section of machine 102 applies label 110 to carton 112. Print and apply machines are known in the art, such as available through Label-Aire, Weber, and Diagraph. RFID labels may also be encoded after being applied to carton 112.

[0031] A conveyer system 114 moves cartons 110, which can be packages, boxes, or any other items on which label 11is to be attached. As each carton 112 passes by the applicator section of machine 102, label 110 with printed barcode or encoded RFID information is attached. Note that barcode, as used herein, may refer to any optically readable format and is not limited to barcodes. Cartons 112 can then be moved along conveyer system 114 for sorting or any other suitable processing.

[0032] As discussed above, label 110 can also be encoded with RFID information, such as from a data stream. Note that print and apply machine 102 is labeled as a unitary device. However, depending on the system and/or required function, machine 102 can be separated into two or more devices, such as for printing, encoding, applying, etc. In one embodiment, the existing information is obtained from a data stream transmitted by a host computer (not shown). The data stream can include commands, information, or instructions for printing or encoding information on a label. Print and apply machine 102 can then process the necessary signal components and use the information to print and/or encode a label.

[0033] In one embodiment, the data stream also contains information about where label 110 should be placed on carton 112. Along with EPC (Electronic Product Code) data, the data stream may also include location information on the carton. For example, this information may be the distance from the leading edge (or relative front) of the carton (X-direction in FIG. 1) and distance from the interior side of the carton (Y-direction in FIG. 1). The Z-direction may also be included within each data stream, or the Z-direction may be set at a default height, which can be changed in the data stream. X and Y direction placement may also have user-set default settings, where distance information is transmitted by the data stream only if one or more of the default settings are changed. This may occur when a different carton is placed on conveyer system 114 or when a different label placement is desired for the same carton. In other embodiments, coordinates for label placement may be sent to printer system 100 separately from the data stream.

[0034] The coordinate information, as discussed above, can be sent from a host computer incorporating any third party software such as any warehouse management software, label printing software, SAP drivers, or any database drivers. If the coordinate information is sent with the data stream, the printer system may print/encode the labels and position print and apply machine 102 at the same time, resulting in increased throughput. Once printer system 100 receives an indication, such as through confirmation signals, that both the label is ready and the applicator is properly position, print and apply machine 102 can be brought down (in the Z-direction) to apply the label. Note that the origination of print and apply machine 102 may be positioned at different locations relative to carton 112. For example, if it is desirable to apply labels to one of the sides of carton 112, print and apply machine 102 may be placed along that particular side.

[0035] FIG. 2 is a block diagram showing a portion of printer system 100 of FIG. 1. A software/host 200 communicates with a server/database 202 and print and apply machine 204. EPC and coordinate information is stored in server/database 202. Such information may be for different labels and cartons and in different languages. A user may program or write information to server/database 202 for specific printing, encoding, and/or application instructions through any suitable interface. Software/host 200 retrieves coordinate information from server/database and may also retrieve EPC data. Software/host 200 then transmits this information to print and apply machine 204, which routes EPC data to a printer/encoder portion and coordinate data to motors, such as X-motor 206 and Y-motor 208. The printer/encoder portion then prints/encodes the label, while the motors move the applicator portion to the corresponding coordinates. Once each motor positions the application portion in the desired location, a signal is sent to print and apply machine 204. Upon receiving signals from all the motors, the label is applied, assuming the label has been printed or encoded.

[0036] In one embodiment, a command parser is used to route the appropriate data to the appropriate destinations. When a data stream that includes both label data and positioning data is received, the command parser may first identify the specific commands for label printing/encoding and the specific data for applicator placement. The command parser then separates the two, and routes the label data to the printer/encoder portion of the system and routes the positioning information to the applicator portion of the system.

[0037] FIG. 3 shows an example command transmitted by software/host 200 to print and apply machine 204. The command in PGL includes instructions to place the label six inches from the leading edge (in the X-direction) and one inch from the bottom of the carton (in the Y-direction) (see FIG. 1). Also included in the command is EPC data for printing a tag. Thus, this example shows a command that includes both barcode information as well as label placement information.

[0038] Referring back to FIG. 2, print and apply machine 204 includes a printer controller 210 and a GPIO (general purpose input/output) module 212 for controlling and performing the above actions. GPIO module 212 functions similarly to an input/output intermediate controller next to printer controller 210, acting as a bridge between the printer portion and the applicator portion. GPIO module 212 can be coupled to or integrated with printer controller 210. In conventional systems, EPC data is transmitted to a print and apply device, which prints/encodes the label. Separately, and with a different interface, X and Y data is sent to a PLC/microcontroller, which controls X and Y motors for label placement. With the present invention, a single interface allows one integrated system using a synchronized approach and a single data stream containing both label and placement data.

[0039] In one embodiment, GPIO module 212 can be driven by any internal printing, encoding or verification event or by external events. Through mappings, GPIO module 212 can generate output events to drive external devices or to control printer internal activities, resulting in more effective management of functions.

[0040] FIG. 4 is a flow chart 400 showing one embodiment for applying a label anywhere on a carton or package. In step 402, label and position information are sent to a print and apply machine. The label information may contain commands, instructions, or data for printing or encoding a label. The position information may contain X, Y, and/or Z coordinates for placement of the label on the carton. Both the label and position information may be transmitted in a single data stream to the print and command machine through a single interface. Next, in step 404, the coordinate data is transmitted to individual motors (e.g., X, Y, and/or Z motors), such as by a printer controller in the print and apply machine. For example, X-coordinate data is transmitted to the X-motor, Y-coordinate data is transmitted to the Y-motor, and Z-coordinate data is transmitted to the Z-motor. Concurrently or subsequently, EPC or label data is transmitted to the printer in step 406. This data is used to instruct the printer portion how to print and/or encode the label.

[0041] Next at step 408, in response to the position information transmitted in step 404, the individual motors are moved into the desired positions. Similarly, at step 410, the printer/encoder portion of the printer system prints or encodes labels according to the EPC data received in step 406. This can be done at the same time as the motor movement of step 408. At step 412, the system determines whether the motors are ready, i.e., in the proper position for label application. In one embodiment, this determination is made by checking to see if the system receives a signal from a motor indicating that it is in the proper position. Once the system receives such a signal from each motor, then the system determines that the motors are ready. At step 414, the system determines whether the label is ready, e.g., when printing or encoding is completed. This step may take place at the same time as step 412 or before or after.

[0042] When the motors are ready (as determined in step 412) and the label is ready (as determined in step 414), the system applies the label in step 416. In one embodiment, when the label is ready to be applied, a signal is sent to the system for application of the label on the carton. Because the system has independent motors to move the applicator portion anywhere over the carton, the label can be applied anywhere on the carton. Furthermore, because the system has a single integrated controller, both the label printing/encoding information and the label positioning information can be sent to a single interface, in a single data stream. This results in a simple, easy to integrate system that enhances throughput, since label printing and applicator placement can be performed at the same time.

[0043] The above-described embodiments of the present invention are merely meant to be illustrative and not limiting. It will thus be obvious to those skilled in the art that various changes and modifications may be made without departing from this invention in its broader aspects. Therefore, the appended claims encompass all such changes and modifications as fall within the true spirit and scope of this invention.

[0044] FIG. 5 illustrates the flow diagram 500 for one implementation of the method of skew accommodation used with the printer system. To start 505, a package is placed into the camera field of view 510. An optical sensor detects the skew angle of the package in an X-direction, Y-direction, and Z-direction 515. In one embodiment, the camera can he any type of orientation and location detection apparatus that contains sensors to detect skew angel of an item. A first motor moves the print and apply device in an X-direction and a supplemental motor rotates the print and apply device along the X-direction axis 520. A second motor moves the print and apply device in a Y-direction and a second supplemental motor rotates the print and apply device along the Y-direction axis 525. Lastly, a third motor moves the print and apply device in a Z-direction and a third supplemental motor rotates the print and apply device along the Z-direction axis 530 until the skew angle is determined to be within an acceptable approach to zero. A controller coupled to the print and apply device and having a single interface is configured to receive a single data stream comprising label data and positioning data from a single data stream. A command parser is configured to receive the single data stream and parse label data to the printer/encoder portion and positioning data to the applicator portion. The applicator portion prints and affixes a label to the package 535.

[0045] FIG. 6 is a perspective view of one embodiment of the printer system using a camera and optical sensor for determining package skew 600. In one embodiment, the camera can be any type of orientation and location detection apparatus that contains sensors to detect skew angel of an item. For that matter, the sensors can be an acoustic sensor, a magnetic field sensor, a wireless sensor, a motion sensor, a laser sensor or an air pressure or a weight sensor or any other types of measurement sensors. In one embodiment, the camera 620 consists of an optical sensor 622 which coverts the optical image of the package 612 to an electrical file, and a lens which focuses the image of the package 612 onto the sensor 622. The sensor 622 is always imaging whenever the printer system 600 is operating, constantly refreshing the image at regular intervals several times per second. A rotation actuator mechanism rotates the camera 620 in an appropriate direction to align the sensor 622 with the package 612. When samples of the image are taken continuously, the skew angle determined by a computer algorithm. The camera 620 continues to be moved in the appropriate direction until the skew angle is determined to be within an acceptable approach to zero. At that time camera 620 motion is stopped. The controller 624 then receives a single data stream comprising label data and positioning data. In response to the position information transmission, the motors 604, 606, 608 and supplemental motors 626, 628, 630 are moved and/or rotated into the desired positions such that a first motor 604 moves the print and apply device in an X-direction and a first supplemental motor 628 rotates the print and apply device along the X-direction axis. Then a second motor 606 moves the print and apply device in a Y-direction and a second supplemental motor 626 rotates the print and apply device along the Y-direction axis. Further, a third motor 608 moves the print and apply device in a Z-direction and a third supplemental motor 630 rotates the print and apply device along the a Z-direction axis until the skew angle is determined to be within an acceptable approach to zero. Similarly, the controller 624 sends the single data stream to a command parser 632, which parses label data to the printer/encoder portion and positioning data to the applicator portion. The printer and apply 602 portion of the printer system prints or encodes labels 610. This can be done at the same time as the supplemental motor 626, 628, 630 movements. The controller 624 determines whether the supplemental motors 626, 628, 630 are ready, i.e., in the proper skew angle for label 610 application. In one embodiment, this determination is made by checking to see if the controller 624 receives a signal from one or more supplemental motors 626, 628, 630 indicating that it is in the proper position. Once the controller 624 receives such a signal from each motor 626, 628, 630, then the controller 624 determines that the motors are ready. Next, the controller 624 determines whether the label 610 is ready, e.g., when printing or encoding is completed. When the motors 626, 628, 630 are ready and the label 610 is ready, the print and apply system 602 applies the label 610. In one embodiment, when the label 610 is ready to be applied, a signal is sent to the print and apply system 602 for application of the label 610 on the package 612. Because the print and apply system 602 has independent motors 604, 606, 608 to move the applicator portion anywhere over the package 612, the label 610 can be applied anywhere on the package 612. Furthermore, because the print and apply system 602 has a single integrated controller 624, both the label printing/encoding information and the label 610 positioning information can be sent to a single interface, in a single data stream. The current invention provides a solution that can eliminate the need to reposition the box to align perfectly with the x, y and z axes for the 3 dimension label printer to function properly and to be able to print the label that is aligned to edges thus saving time in aligning the boxes before affixing the label. This revolutionary design yields unexpected results and enables the processing of affixing labels to boxes to be 90% more efficient than the previous embodiment.

[0046] FIG. 7 shows the printer system with a skewed box in view of the x, y, z axes: The printer system 700 is coupled to an X-motor 704, a Y-motor 706, a Z-motor 708, a supplemental X-motor 728, a supplemental Y-motor 726, and a supplemental Z-motor 730. X-motor 604 enables package 612 to move in the X-direction, as shown, such as by driving mechanisms or the machine itself. A camera 720 comprising a sensor 722 converts the optical image of the package 712 to an electrical file. A rotation actuator mechanism rotates the camera 720 in an appropriate direction to align the sensor 722 with the package 712. When samples of the image are taken, the skew angle determined by a computer algorithm. The camera 720 continues to be moved in the appropriate direction until the skew angle is determined to be within an acceptable approach to zero. At that time camera 720 motion is stopped. The controller 724 then receives a single data stream comprising label data and positioning data. In response to the position information transmission, the supplemental motors 726, 728, 730 are moved into the desired positions such that a first motor 704 and a first supplemental motor 728 moves along the X-direction and rotates the package 712 along the X-direction axis; a second motor 706 and a second supplemental motor 726 moves along the Y-direction and then rotates the package 712 along the Y-direction axis; and a third motor 708 moves along the Z-direction axis and a third supplemental motor 730 rotates the package 712 along the Z-direction axis. With three degrees of freedom, printer system 700 is capable of applying a label, tag, or other article anywhere on a package 712, where the package can be positioned at different angles. Once printer system 700 receives an indication, such as through confirmation signals, that both the label is ready and the print and apply machine 702 is properly positioned, print and apply machine 702 can be brought down (in the x-axis direction) to apply the label.

[0047] FIG. 8A shows two label printer application systems with robotic arms, represented as R1 802 and R2 804, interfacing with one printer, P 806, wherein one printer P 806 is being used with both R1 802 and R2 804 systems. This allows the printer to more frequently and continuously function, therefore reducing the downtime or rest period of the printer P 806. Effectively, having two systems R1 802 and R2 804 with only one printer P 806 could function equally efficiently as having two systems with two printers. In one embodiment, the R1 802 and R2 804 systems are conveyor belts, and the both systems can share the use of one printer P 806.

[0048] Naturally, the printer would require more maintenance than the system because the printer requires ink, toner, etc. that can be depleted. Furthermore, printer also requires a label on which the printer can print. Therefore, printer requires more maintenance and therefore more down time than the system that uses software to process information. As a result, it may be desirable to have a printer on standby.

[0049] FIG. 8B shows two label printer application systems R1 802 and R2 804 with two printers P1 806 and P2 808, such that when the first printer P1 806 is taken offline for maintenance or any other reason, the second printer P2 808 may be hot-swapped in place of the first printer P1 806. This reduces, if not completed eliminates, any down time that the first printer P1 806 may cause as a result of maintenance. In one embodiment, there are two printers P1 806 and P2 808 in each of the X, Y, and Z-axis. The first system R1 802 can move the X-axis printer P1 806 in the X-direction and if the printer P1 806 is under maintenance, R1 802 can move the X-axis printer P2 808 in the X-direction instead of P1 806. Similar R1 806 may move the Y-axis printer and Z-axis printer in the Y-direction and Z-direction respectively, as well as the standby or supplemental Y-axis printer and Z-axis printer in their respective directions.

[0050] FIG. 9A shows three label printer application systems, R1 902, R2 904, and R3 906, interfacing with two printers P1 908 and P2 910, wherein the first printer P1 908 is the primary printer and the second printer P2 910 is the standby printer. Therefore, if the first printer P1 908 needs maintenance for changing the toner or to cool down or for repair, the second printer P2 910 would be hot-swapped into the place of the first printer P1 908 and would continue printer labels as if it where the first printer P1 908. There would be virtually no down time despite the first printer P1 908 being unable to proceed with printing the labels. There could be as many printers as desirable and necessary interfacing with one or more systems. In one embodiment, the R1 902, R2 904, and R3 906 systems are conveyor belts interfacing with the two printers P1 908 and P2 910. In another embodiment, there are two printers P1 908 and P2 910 in each of the X, Y, and Z-axis. Thus, for each axis, the three systems R1 902, R2 904, and R3 906 can interface with P1 908 and, if printer P1 908 is down for maintenance, the three systems R1 902, R2 904, and R3 906 can interface with P2 910 in order to continue operation without interruption.

[0051] FIG. 9B shows two label printer application systems, R1 902 and R2 904, with three printers P1 908, P2 910, and P3 912, wherein the first printer P1 908 is the primary printer and the rest of the two printers P2 910 and P3 912 are standby printers. In another embodiment with three printers P1 908, P2 910, and P3 912, the first two printers P1 908 and P2 910 are the primary printers and the third printer P3 912 is the standby printer. If either one of the first two primary printers P1 908 and P2 910 requires maintenance, the third standby printer P3 912 would be hot-swapped in and perform instead of one of the primary printers P1 908 and P2 910. Similarly, in one embodiment, the R1 902 and R2 904 systems are conveyor belts interfacing with the three printers P1 908, P2 910 and P3 912. In another embodiment, there are three printers P1 908, P2 910 and P3 912 in each of the X, Y, and Z-axis. Thus, for each axis, the two systems R1 902 and R2 904 can interface with P1 908 and, if printer P1 908 is down for maintenance, the two systems R1 902 and R2 904 can interface with P2 920 and P3 912 in order to continue operation without interruption. This effectively allows the system to continue to operate without interruption.