Embodiments of the present disclosure relate to mail handling and processing systems for mail and related articles and, more particularly, to systems and methods for automatically loading mail from sortation output pockets into a receiving tray designed for the purpose of moving items to a feed mechanism or to dispatch and shipping.
Mail received at a post office or other location is sorted or otherwise processed so that it can be directed to a desired location. To accomplish this function, sortation machines with output pockets are used to sort various mail products. Typically, the product that arrives in the output pockets of a sortation machine is removed manually and placed in movable containers, trays, or other containing devices so that it can be moved through additional sortation processes or dispatched to arrive at its intended destination. As an example, letters sorted on a Delivery Bar Code Sorter (DBCS) arrive in letter trays. An operator manually moves the letters from the trays onto a feeder load ledge to begin the sort process. Once sorted to the sorter pockets of the DBCS, an operator removes the letters from the output pockets and places them in a labeled letter tray so they can be transported to the next processing step. In addition to being manually intensive, this process is prone to operator error. For example, an operator may accidently drop a handful of mail or place the mail in the wrong tray, thereby losing an intended order of the mail or sending it to the wrong location. A portable bridge is sometimes used to bridge the distance between individual output pockets and corresponding trays, but this type of bridge is cumbersome and takes time to transport from one set of output pockets/trays to another.
Therefore, it is now recognized that a need exists for an efficient and simple to operate mechanism that would eliminate the errors that naturally occur through operators manually removing items from sorter output pockets and placing those items in containing devices for processing or delivery.
In accordance with the above, presently disclosed embodiments are directed to a system and method for loading automation trays in a mail stacker/sorter without human intervention. The system includes a mail stacker having at least one output pocket. The mail stacker may be a Delivery Bar Code Sorter (DBCS), or any other mail sorting machine, designed to receive mail product and to sort/stack at least a portion of the mail product into the output pocket. The system also includes a shelf disposed under the output pocket, and this shelf may be a part of the mail stacker. The system utilizes an automated mail tray having a bottom plate that is selectively moveable between an elevated position and a lowered position. The automated mail tray may be removably disposed on the shelf in order to receive mail product transferred from the output pocket to the elevated bottom plate of the automated mail tray. Specifically, the elevated bottom of the automated mail tray may interface with a lower portion of the output pocket so that mail product that is stacked into the output pocket is supported on the elevated bottom plate of the mail tray. After receiving the mail product on the elevated bottom plate, the automated mail tray may lower the bottom plate to the lowered position so that the mail product is transferred from the output pocket to a position fully situated in the automated mail tray. At this point, the automated mail tray filled with mail product may be removed from the shelf and replaced with an empty automated mail tray, and the process may be repeated.
For a more complete understanding of the present disclosure and its features and advantages, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which:
Illustrative embodiments of the present disclosure are described in detail herein. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation specific decisions must be made to achieve developers' specific goals, such as compliance with system related and business related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of the present disclosure. Furthermore, in no way should the following examples be read to limit, or define, the scope of the disclosure.
Turning now to the drawings,
The mail stacker 12 may also include a number of shelves disposed between adjacent rows of the output pockets 18, as described in detail below. The shelves may be arranged in columns and/or rows to match the output pockets 18, and the shelves may function together as a storage rack for holding one or more receiving containers used to collect sorted mail. The disclosed mail sortation and transportation system 10 may be designed to control and automate the transfer of mail between one or more output pockets 18 of the mail stacker 12 and corresponding receiving containers, as described in detail below.
It should be noted that the disclosed mail stacker 12 may include any desirable type or size of mail stacker and/or sorter. For example, the mail stacker 12 may have 48, 206, or any other desirable total number of output pockets 18. The mail stacker 12 may include these output pockets 18 assembled in one, two, three, four, five, six, or more tiers stacked one over the other, depending on the height of the individual pockets 18 and the height of the receiving containers used to collect the mail from the output pockets 18. The mail stacker 12 may have the same number and configuration of shelves as the mail stacker 12 has rows of output pockets 18.
The tray storage and movement system 14 is disposed adjacent the mail stacker 12 and may be used to store receiving containers. For example, the tray storage and movement system 14 may include racks upon which to store receiving containers that have been filled with mail product from the mail stacker 12 or empty receiving containers to be provided to the mail stacker 12. The tray storage and movement system 14 may include a storage rack having more slots for holding receiving containers than the number of shelf positions in the mail stacker 12, thus enabling the tray storage and movement system 14 to store the filled or empty receiving containers away from the shelves.
In some embodiments, the receiving containers may be transported between the tray storage and movement system 14 and the mail stacker 12 manually by an operator. In other embodiments, however, the tray storage and movement system 14 may be designed to automatically move a filled receiving container from a given shelf and to replace it with an empty receiving container. To that end, the tray storage and movement system 14 may utilize roller conveyors, elevators, robots, and other types of automated transportation devices. The tray storage and movement system 14 may be fully automated to read tagged receiving containers and to use that information to present filled receiving containers in a desired order for a second pass through the mail stacker 12 (arrow 22) or for dispatch (arrow 24).
The tray to feeder path 16 is a conveyor that moves receiving containers filled with mail product to an upstream location (e.g., feeder) 26 of the mail stacker 12. From this upstream location 26 of the mail stacker 12, the mail product is sorted into the output pockets 18 of the mail stacker 12. The tray to feeder path 16 may provide receiving containers holding new unsorted mail to the mail stacker 12. In some embodiments, the tray to feeder path 16 may also provide receiving containers holding mail that has already been sorted by the mail stacker 12 and subsequently deposited into the receiving containers and moved to the tray storage and movement system 14. In this case, the tray to feeder path 16 may be controlled to transport the sorted mail back to the upstream location 26 of the mail stacker 12 (arrow 22) so that the mail stacker 12 can perform a second pass on sorting and stacking the mail product, or to transport the sorted mail to a dispatch location (arrow 24). As illustrated, the tray to feeder path 16 may be elevated above the mail stacker 12 so that the tray storage and movement system 14 is able to automatically move filled receiving containers of mail from the mail stacker 12 onto the tray to feeder path 16.
In the illustrated embodiment, the mail stacker 12 may include four rows 54 of output pockets 18 that can be filled with mail product 50 that is sorted and stacked via the mail stacker 12. However, it should be noted that other numbers and arrangements of the output pockets 18 may be utilized in other embodiments of the mail stacker 12.
Below each output pocket 18 is a shelf 56 generally extending outward from the mail stacker in the same direction as the output pocket 18. As shown, the shelves 56 may form part of the mail stacker 12 along with the ouput pockets 18. The shelves 56 are generally arranged one under each of the output pockets 18 to support a corresponding automated mail tray 52 to receive mail product 50 transferred from the output pocket 18. The shelves 56 generally have an open back side 58 that enables filled mail trays 52 to be removed from the shelves 56, for example, for transportation away from the mail stacker 12.
As illustrated, the output pockets 18 of a given mail stacker 12 are generally standardized, so that they are approximately the same size and shape for uniform mail collection and transfer to the automated mail trays 52. Similarly, the mail trays 52 may be standardized sizes that match the mail product capacity of the corresponding output pockets 18.
To aid in the transfer of mail product 50 from the output pocket 18 to the automated mail trays 52, each mail tray 52 may feature a moveable bottom plate for supporting the mail product 50.
In some embodiments, the moveable bottom plate 70 may be raised by exerting force under the bottom plate 70 and held in place while mail is being loaded onto the bottom plate 70. In some embodiments, the automated mail tray 52 may include an actuation mechanism 78 that automatically lifts the bottom plate 70 relative to the other portions (e.g., side walls 76) of the mail tray 52. In other embodiments, the shelf 56 upon which the automated mail tray 52 is disposed may feature an actuation mechanism (not shown) that selectively pushes up against the bottom plate 70 to move the bottom plate 70 to the elevated position 72 relative to the other portions (e.g., side walls 76) of the mail tray 52. Other mechanisms may be utilized in other embodiments for automatically moving the bottom plate 70 of the mail tray 52 between the elevated position 72 and the lowered position 74.
Turning back to
The mail tray 52 may be pushed outward along the shelf 56 until the mail tray 52 reaches a position substantially aligned with and disposed just below the output pocket 18. To that end, the shelf 56, the mail tray 52, and/or the output pocket 18 may include one or more alignment features (not shown) for aligning the automated mail tray 52 with the output pocket 18. In some embodiments, the automated mail tray 52 may be aligned with the output pocket 18 such that the bottom plate 70 of the automated mail tray 52 in the elevated position 72 is flush against the output pocket 18.
The mail stacker 12 may be operated to sort and stack mail product 50 into the bottom of the output pocket 18. In some embodiments, the mail product 50 may be sorted and stacked into desired output pockets 18 based on the functions of a Delivery Bar Code Sorter (DBCS). The mail stacker 12 may stack the mail product 50 until it generally fills the entire length of the output pocket 18. As an example, the output pocket 18 on the upper row 54A of the mail stacker 12 in
In some embodiments, filling of the output pocket 18 may take place only after a mail tray 52 has been disposed in position directly under and/or aligned with the output pocket 18.
In such embodiments, the output pocket 18 may be configured with an opening 82 at the bottom, as shown in
In other embodiments, filling of the output pocket 18 may take place before a mail tray 52 is disposed in position beneath the output pocket 18. In such embodiments, the output pocket 18 may feature a moveable bottom 90, as shown in
Turning back to
The automated mail tray 52 disposed on the shelf 56 of the second row 54B of the mail stacker 12 includes the mail product 50 held in the lowered position within the mail tray 52. At this point, the mail product 50 is fully positioned within and supported by the automated mail tray 52. The tray 52 may then be extracted (arrow 112) out the back side 58 of the shelf 56 in the mail stacker 12 for storage or transportation to another location. For example, the tray 52 may be extracted out the back side 58 (either manually or automatically via a controlled mechanism) and sent to a storage grid, such as the above described tray storage and movement system 14. In some embodiments, the shelves 56 may be equipped with rollers 114 to facilitate insertion and removal of the automated mail trays 52. In other embodiments, the shelves 56 may themselves function as conveyors that can be controlled to facilitate movement of the automated mail tray 52 along the shelf 56.
As shown on the output pocket 18 of the third row 54C, the mail stacker 12 may begin to sort and stack additional mail product 50 into the output pocket 18 while the automated mail tray 52 is being removed off the corresponding shelf 56. Again, the output pocket 18 may continue to support this mail product 50 from below via a moveable bottom (e.g., 90 of
The control system 130 utilizes the at least one processor component 132 and the at least one memory component 134 to monitor and/or control various mail stacking and loading operations at the mail sortation and transportation system 10. For example, one or more processor components 132 may be designed to execute instructions encoded into the one or more memory components 134. Upon executing these instructions, the processors 132 may monitor the operational states of certain components of the mail sortation and transportation system 10. In addition, the processors 132 may control operation of various components (e.g., mail stacker 12, mail tray 52, output pocket 18, tray storage and movement system 14, etc.), of the system 10 based on sensor feedback. This may help to control the loading and transportation of the mail trays 52 throughout the system 10.
As shown, the processors 132 may be coupled to a user interface 136 that enables an operator to input instructions for execution by the control system 130. The control system 130 may output certain control signals to the system components based on the commands received from an operator at the user interface 136. The user interface 136 may also output data relating to the operational state of the mail sortation and transportation system 10. For example, the user interface 136 may provide an operator with information about each mail tray 52 that is disposed in the mail stacker 12, such as a position of the mail tray 52, whether the mail tray 52 is full or empty, and a position of the moveable bottom plate 70. In addition, the user interface 136 may output alerts to the operator in response to unexpected events encountered during mail sorting, stacking, loading, and transportation operations.
As shown, the control system 130 may be communicatively coupled to a number of sensors 138 disposed about the mail sortation and transportation system 10. These sensors may include, for example, optical sensors, acoustic sensors, proximity sensors, load cells, and/or others. Based on feedback from these sensors 138, the control system 130 may determine when to actuate certain components of the system 10. The control system 130 may also be communicatively coupled to a number of controllable components (actuators 140) located throughout the mail stacker 12, the automated mail trays 52, the output pockets 18, the tray storage and movement system 14, and/or the tray to feeder path 16. The control system 130 may actuate certain of these controllable components 140 based on sensor feedback.
For example, the control system 130 may actuate the moveable bottom 90 of the output pocket 18 to horizontally slide out of the way only once a sensor 138 determines that a corresponding mail tray 52 is disposed beneath the output pocket 18 and has its bottom plate 70 in the elevated position. In addition, the control system 130 may control operation of the mail stacker 12 such that the mail stacker 12 prevents mail product 50 from being fed into a particular output pocket 18 that is in the process of having the corresponding mail tray 52 changed (transitioned off the shelf 56 and replaced by another mail tray 52) until the transition is complete. This may eliminate mail product 50 from being rejected for an unavailable stacker destination. In embodiments where the output pocket 18 includes a moveable bottom 90, the control system 130 may control the mail stacker 12 to fill the output pocket 18 only once sensor feedback indicates that the moveable bottom 90 has been actuated to cover the opening in the bottom of the output pocket 18. In embodiments where the output pocket 18 includes an opening 82 at the bottom, the control system 130 may control actuation of the bottom plate 70 of the automated mail tray 52 so that the bottom plate 70 lowers only once a sensor 138 detects that the output pocket 18 is full. Various other control and automation processes may be performed by the control system 130 to facilitate efficient operation of the mail sortation and transportation system 10.
The disclosed embodiments may enable various mail sorting, stacking, and transportation operations to be performed without operator intervention. The controlled actuation of the bottom plate 70 of each mail tray 52 may facilitate a fully automated and streamlined loading of mail product 50 from the stacker output pockets 18 into transportable mail trays 52, which can then be removed from the mail stacker 12. By automating this process of loading the mail trays 52, the disclosed embodiments enable the mail stacker 12 to operate as a standalone unit that does not depend on a human operator to move sorted mail into receiving containers. Further, all human errors, such as dropped or disordered mail product, may be eliminated from the process of loading sorted mail into respective mail trays.
Although the present disclosure and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the disclosure as defined by the following claims.
This application claims priority to U.S. Provisional Application Ser. No. 62/268,274, entitled “Automated Mail Tray Loading System and Method,” filed Dec. 16, 2015, which is herein incorporated by reference in its entirety.
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Number | Date | Country | |
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20170173639 A1 | Jun 2017 | US |
Number | Date | Country | |
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62268274 | Dec 2015 | US |