Vertical justification system

A device and system for registering or justifying product such as mail pieces in a vertical position for future processing of such mail pieces. The system includes a mounting block having an angled bore and a driven alignment mechanism mounted within the angled bore. The driven alignment mechanism includes a shaft assembly mounted in the angled bore such that the shaft assembly is at approximately a same angle as the angled bore. At least one surface is mounted to the shaft assembly which, when contacting a product, is driven and provides a downward correction vector to the product for vertically aligning the product.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention generally relates to a justification system and, more particularly, to a vertical justification device for vertically aligning skewed product or misaligned product for subsequent processing.

2. Background Description

The sorting of mail is a very complex, time consuming task. In general, the sorting of mail is processed though many stages, including back end processes, which sort or sequence the mail in delivery order sequence. These processes can either be manual or automated, depending on the mail sorting facility, the type of mail to be sorted such as packages, flats, letter and the like. A host of other factors may also contribute to the automation of the mail sorting, from budgetary concerns to modernization initiatives to access to appropriate technologies to a host of other factors.

In general, however, most modem facilities have taken major steps toward automation by the implementation of a number of technologies. These technologies include, amongst others, feeding devices, letter sorters, parcel sorters, advanced tray conveyors, flat sorters, optical recognition systems, singulators and the like. As a result of these developments, postal facilities have become quite automated over the years, considerably reducing overhead costs.

But, in implementation, certain automations may require additional attention in order to efficiently process the mail pieces (product). For example, currently, it is known to induct letters, flats and products, in general, into a sorting system using feeders. To accomplish this induction, the products are first vertically stacked near a conveying system. The product are then fed into the conveying system, at which time indicia such as, for example, delivery destination information, is printed (e.g., sprayed) on a surface of the product. This information may be in the form of bar coding or the like. The delivery destination information is then read by one or more scanners, for example, to then be reconciled by a controller for future sorting, sequencing or other processing of the product, e.g., sequencing the product into walk order sequence.

Prior to spraying or printing the delivery information on the product, the product must be vertically justified with respect to an edge of the product. This will ensure that the indicia will be properly aligned on the product. If, however, the indicia are not properly aligned on the product, e.g., partially sprayed on the product, misaligned on the product, etc., the reading device will not be able to read such information and, in turn, the system will not be able to reconcile such information for sequencing or further processing. In these situations, the product will be ejected into a reject bin for manual sort, which decreases, considerably, the efficiency of the sorting and sequencing system.

Currently, to align a skewed product or “drive” the product onto the transport deck of the system, a traditional leveler is provided with the feeder. The traditional leveler is a front end system which includes opposing, vertically aligned belts, usually in length of two or three feet depending on the induction speed of the system. The belts are separated from one another in order to allow skewed or other incorrectly fed product to be inducted therebetween. In this manner, for example, as the skewed product passes through the opposing, vertically aligned belts, the product will settle, e.g., fall, due to gravity. By the time the product exists the system, the product should be vertically aligned on a transport deck or ledge of the system, on one edge.

However, there are disadvantages to these traditional leveler systems. For example, the opposing, vertically aligned belts are of a considerable length in order to allow gravity to align the product. This is especially true in cases of increased feeder throughput, where the induction speed of the product is increased. Basically, in these situations, the opposing, vertically aligned belts must be lengthened in order to allow the product to settle due to gravity. This is simply because the induction speed of the product has increased which, in turn, requires additional processing time for the product to settle. This, of course, increases the footprint of the system, even more, thus requiring additional warehouse or processing floor space.

Additionally, traditional levelers have difficulty justifying or registering lighter product. For example, the lighter product have a tendency to float between the opposing belts. Because of this floating phenomenon, regardless of the length of the leveler, some product will never become justified onto the transport deck. Also, these lighter product also have a tendency to “cling” to one of the belts, in which case the product again is not properly registered. In any of these situations, the processing of the product will be affected, which will affect the overall processing throughput of the system.

The invention is directed to overcoming one or more of the problems as set forth above.

SUMMARY OF THE INVENTION

In a first aspect of the invention, a device for vertically aligning product includes a mounting block having an angled bore and a driven alignment mechanism mounted within the angled bore. The driven alignment mechanism includes a shaft assembly mounted in the angled bore such that the shaft assembly is at approximately a same angle as the angled bore. At least one surface is mounted to the shaft assembly which, when contacting a product, provides a substantially downward correction vector, which may be at an angle, to the product for vertically aligning the product.

In another aspect of the invention, a system for aligning product includes a driven alignment mechanism positioned at an angle of greater than 0 degrees from the vertical in a direction of product travel. The driven alignment mechanism includes a shaft assembly and at least one freely rotating assembly mounted to the shaft assembly. A drive mechanism opposes the driven alignment mechanism and drives the freely rotating assembly when a product passes between the drive mechanism and the freely rotating assembly.

In yet another aspect of the invention, a system for aligning mail pieces includes a driven alignment mechanism mounted within an angled bore. The driven alignment mechanism includes a shaft assembly and at least one freely rotating surface mounted to the shaft assembly. A driving conveyor system is positioned proximate the driven alignment mechanism and includes a first belt drive and a second, opposing belt drive. The at least one freely rotating surface is positioned proximate the second, opposing belt drive such that mail pieces being transported by the second, opposing belt drive and passing between the second, opposing belt drive and the at least one freely rotating surface drives the at least one freely rotating surface. The at least one freely rotating surface, when contacting the mail pieces, provides a downward correction vector to the mail pieces for vertically aligning the mail pieces.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

The invention is directed to a justification device and more particular to a device or system capable of vertically aligning products such as, for example, flats and other mail items (i.e., product), into vertically aligned positions for future processing, delivery or warehousing. In aspects of the invention, the product may be inducted into the system in a vertical orientation, with some or all of the product being skewed or inducted above the transport deck. In aspects of the invention, the product will be vertically justified in a minimal amount of space, decreasing the current footprint of known systems.

The system of the invention significantly reduces processing times for sequencing both flats and mail pieces or other disparate products in delivery point sequence using, in embodiments, a skew mechanism. The skew mechanism is easily retrofitted onto known systems, and can be easily adapted to any known product induction speed, while vertically aligning the product without the need to increase the footprint of the system. In fact, by using the skew mechanism, the footprint of known leveler systems can be significantly reduced, upwards of 50% or more. The skew mechanism is adjustable and may be a passive device driven by current belt drives used in a feeding system. Other applications such as warehousing and storage applications are also contemplated for use with the invention.

System of the Invention

Referring now toFIG. 1, a general schematic diagram of the vertical justification system of the invention is shown. In the embodiment ofFIG. 1, the vertical justification system is depicted as reference numeral100and includes a first feeder or conveyor102and a second, feeder or conveyor104. In embodiments, the first feeder102is a belt drive, and the second feeder104is a pair of opposing belt drives104aand104b, with belt drive104bhaving a shorter length than that of belt drive104a. In one application, the feed rate capacity of the belt drives may be approximately 40,000 letters per hour and approximately 10,000 flats per hour. Those of ordinary skill in the art should recognize, though, that other feeding capacity rates may also be used with the invention, and the feeding capacity described herein is provided for illustrative purposes.

Still referring toFIG. 1, an adjustment mechanism (e.g., skew adjustment mechanism)106is positioned at a distal end of the belt drive104b, and opposed to the belt drive104a. In one embodiment, the skew adjustment mechanism106is separated from the belt drive104aby approximately 1–2 mm in order to allow product to pass therebetween. However, it should be recognized that the distance between the skew adjustment mechanism106and the belt drive104amay vary depending on the particular application. The skew adjustment mechanism106may also be adjustable by, for example, being spring loaded or of a semi compliant material such as polyurethane, in order to adjust a distance between the skew adjustment mechanism106and the belt drive104a.

In one aspect of the invention, the skew adjustment mechanism106is comprised of one or more rollers106aaxially mounted to a shaft assembly122a. The one or more rollers106amay, in one embodiment, be composed of semi compliant material in order to adjust a distance between the skew adjustment mechanism106and the belt drive104a. The rollers106amay be freely rotatable about the shaft, which is adjustable to tilt at different angles with respect to a transport deck108of the system100. The rollers may equally be representative of a belt, band, stationary or rotating low friction surface or other conveying device. The rollers106amay be passive rollers driven by the belt drives104aand104b, and more particularly, by the product passing between the belt drive104aand the skew adjustment mechanism106. The components of the skew adjustment mechanism106are discussed in more detail with respect toFIG. 3.

A leveler system109is positioned at a remote end of the belt drive104a, and proximate the skew adjustment mechanism106. The leveler system109includes opposing belts109aand109band a flat conveying belt109c(transport deck), orthogonally positioned with respect to the opposing belts109aand109b. In this application, the footprint of a traditional leveler system can be significantly reduced from two or more feet to one foot in length or less. This will significantly decrease the required flooring space required for the system of the invention.

A camera, optical reading device or other type of reading device110and/or printer112, are positioned downstream of the leveler system109. A control “C” may also be used with the system100in order to control the timing of the printing and reading of the product. In embodiments, the camera or reading device is designed to read the delivery point or other pertinent product information provided on each product. In further aspects of the invention, the product information is first sprayed or printed by the printer and, after a second or subsequent pass through the system, read by the camera or other reading device and reconciled by the controller “C”, in a known manner.

FIG. 2shows a side view of the system100. In this view, it is shown that the skew adjustment mechanism106is positioned at an angle with respect to the other components of the system100. In this manner, product “P” will be directed downwards, towards the transport deck as the product passes by the skew adjustment mechanism106. The skew adjustment mechanism106is initially a passive device, in one embodiment, and is driven or powered by the general flow of the product.

FIG. 3shows an exploded view of the skew adjustment mechanism106. In this aspect of the invention, the skew adjustment mechanism106includes a roller assembly120, preferably a shaft, mounted within a mounting block122and including rollers106a.These rollers106amay be comprised of semi compliant materials. In one aspect of the invention, the shaft120includes a several different diameters, one of which is a smaller diameter for engaging within an angled bore124of the mounting block. In this embodiment, the smaller diameter of the shaft will include a flat surface120afor engaging with set screw126which fixes the shaft to the mounting block122.

The angled bore124may be at an angle of approximately15degrees from vertical; however, the angle may be range from slightly greater than 0 degrees to slightly less than 45 degrees from the vertical in a direction of product travel. This angle will permit the roller assembly120to be seated within the angled bore at such an angle. One or more rollers106aare freely rotatable about the shaft, although a belt or other mechanism may be mounted to the shaft.

In another aspect of the invention, an angled slot128may be provided within the mounting block122. The angled slot128allows the shaft to be adjustable mounted on the mounting block122at several predetermined angles ranging from slightly greater than 0 degrees to about 45 degrees from vertical, although other angles are also contemplated by the invention. The shaft may be adjustable via many types of mechanism such as, for example, a rack and pinion geared system, a belt, a locking screw, a pawl system and the like, generally represented as reference numeral130. The mounting block122is mounted to the system100and preferably a portion of the transport deck via bolts132or other fastening mechanism.

Method of using the of the Invention

In one use, the product is initially inducted into the system, generally in a vertical orientation. However, at this operational stage, the product may be skewed (i.e., the front and rear edges of the product are not in vertical alignment) or positioned above the transport deck. As the product passes the skew adjustment mechanism, the skew adjustment mechanism applies a predetermined downward angled force, depending on the angle of the skew adjustment mechanism. In this manner, if the product is traveling above the transport deck or is skewed, the change in vector will be provided by the skew adjustment mechanism106thus forcing the product into or close to the proper orientation prior to entering into the leveler system. That is, the skew adjustment mechanism106will provide a downward correction vector to the product, which in one embodiment is an angled downward correction vector. Once in the leveler section, the product will be allowed to settle, if necessary, to correctly orient the product for future processing.

This implementation provides a significant total realized throughput increase of the system; that is, accelerates the correction process compared to a traditional leveling system, alone. In addition, the skew adjustment mechanism will ensure that any product, regardless of the induction speed, will be correctly registered or vertically justified onto the transport deck for future processing (e.g., printing and reading of product information). Also, the skew adjustment mechanism will prevent the lighter product from floating between the opposing belts of the leveler system, in addition to preventing the lighter product from clinging to a belt of the leveler system. This is due, in part, to the downward forces applied by the skew adjustment mechanism on the product prior to entering into the leveler system. Lastly, the use of the skew adjustment mechanism106will significantly decrease the size of the leveler section.