JP7397162B2 - Distance sensing conveyor package management system that measures and controls the density of parcels on a conveyor - Google Patents

Description

(Cross reference to related applications)
This application claims priority from U.S. Provisional Patent Application No. 62/874,902, filed July 16, 2019, which is incorporated herein by reference in its entirety.

The present invention relates to the field of using different sensing and detection methods to detect and control parcel flow density on a conveyor.

Conveyor systems often function to align and space articles on the conveyor system to be processed by downstream sorting equipment. Conventional conveyor systems typically include controlling the articles so that they leave the guiding subsystem with gaps of approximately the desired length between or beside them. The desired gap may be variable depending on the length and/or width of the pair of articles defining the gap, or the desired gap may be constant. Regardless of the criteria used to determine the desired gap length, the gap serves the purpose of facilitating article sorting. Sorting systems often work more effectively when the items being sorted have a certain minimum gap between them. However, gaps above this minimum typically reduce the throughput of the conveyor system. It is desirable to create a gap that balances sorting criteria while maximizing the throughput of the sorting and singulator equipment. However, at guidance points, where parcels are conveyed from various supply points to multiple conveyors, such as truck unloading stations, maximum efficiency can be achieved by moving as many parcels as possible in a given area of the conveyor. .

Variations in the amount of product coming in on the various feed belts create imbalances in different merge areas of the conveyor system and create large empty spots in the collector belt, singulator belt, and sorting area. This fact causes inefficiencies, unnecessary investments in equipment, and a reduction in the overall throughput of the sorting equipment. Traditional flow management systems count packages and/or control the speed of the conveyor to orient the packages or combine them into a single package to achieve the desired distance between them for processing. Form the smallest gap. Examples of these devices are described in the following patents and/or publications:

U.S. Pat. No. 5,165,520 discloses a conveyor system that provides spacing between parcels on a belt, includes a camera system to recognize overlapping or crowding of parcels, and redirects problem parcels. US Pat. No. 8,061,506 uses information gathered from optical sensors or cameras to recognize or generate gases (gaps?) on the collector belt and fill these gaps with packages from the feed belt. It is disclosed that articles are merged onto a conveyor using a conveyor. However, Schafer does not discuss how to process information from a camera or optical sensor to control its concentration. The publication (WO 2000/066280) describes how cameras are used to determine the number of parcels and this information is used to build vehicles such as parcel feeder conveyors, acceleration conveyors, buffer conveyors, singulators, and transport conveyors. A system for controlling a speed conveyor is disclosed. However, this literature does not disclose or suggest the idea of controlling the transport speed to maximize the area covered on the conveyor as a function of occupancy on the conveyor or immediately in front of the singulator. . U.S. Pat. No. 6,471,044 discloses that images are transferred to a control system where they are interpreted to adjust the speed of parcel feeder conveyors, buffer conveyors, acceleration conveyors, singulators, and transport conveyors. Although determining the number of packages and the average size of the packages is disclosed, the density of packages on a given area of the conveyor is not disclosed. U.S. Pat. No. 5,141,097 discloses analyzing an image provided by a camera to display the number of packages present in this image and increasing the speed of the conveyor to obtain a desired throughput. ing. U.S. Pat. No. 6,401,936 monitors parcel flow to separate individual items from a coarse singulator through a system used in conjunction with a downstream singulator, hold-and-release, or strip conveyor. A detection system for identifying and/or tracking is disclosed. A control system is utilized in conjunction with the detection system to adjust the flow of articles through the system by increasing the speed of the conveyor.

Conventional systems rely on methods that count carton feet or parcels discharged from a container unloading conveyor and adjust the speed of the unloading conveyor to ensure singulators and sorters manageable levels. Utilize methods that maintain input flow. The goal is to keep the system fed without overfeeding. The current FDXG system has a sorting capacity of 12,150 parcels per hour (pph) with a gap of 12 inches at 540 feet per minute (fpm) and an average of 20 inches. As a result, system throughput efficiency is limited, with sustained performance typically expected to be only about 60% of sorting capacity. A control system that maximizes the occupancy and density of packages in a given area of the receiving conveyor for unloading the packages, as well as rail vehicles, airplanes, for directing the goods to the appropriate sorting system and controlling the transport speed of the goods. A mechanism for sensing the physical characteristics of a package from a transportation vehicle, such as a vehicle, ship, or truck, is needed.

The present invention provides different sensing methods for determining the 1D linear, 2D area, or 3D volumetrically of parcel flow density at selected sections of a feed conveyor. and detection methods to increase the density or volume of parcels in selected areas of the receiving conveyor by determining conveyor speed ratios that are proportional to the ratio of the desired density to the current density. Regarding the areas to be adjusted.

The density measuring device recognizes and maximizes the utilization of the conveyor's surface area. Sensing and detection devices determine the one-dimensional linear, two-dimensional areal, or three-dimensional volume of parcel flow density in selected areas of the conveyor and determine the current The speed ratio of the feed conveyor and the receive conveyor is adjusted to be proportional to the ratio of the desired density to the density to improve the performance and throughput of the conveyor system. The sensing and/or detection device is located at the flow entry point or transition point between the feeder conveyor and the receive conveyor. The control algorithm determines the area, volume or density of individual items, the rate of speed or velocity at which individual objects pass through selected areas of the feed and receive conveyor surfaces, and Recognize the area utilization of the feed conveyor and the receive conveyor to maintain a desired density of packages on the surface of the receive conveyor.

The bulk parcel flow management system comprises or consists of a density-based detection system that recognizes belt area utilization and parcel counts. The system's congestion detection device is located at the flow entry point and at the singulator. The control algorithm requires recognition of the individual items, the rate at which the individual objects pass, and the area utilization of the collector belt. Average parcel size (area or volume), including length, width, and height, may be considered as well. Additionally, parcel density or weight may be considered in the utilization of conveyor surface area. The present invention improves the area and/or or provide a means for increasing volume and/or density. Conveyor package management systems can also identify, locate, or track packages, parcels, or other items on a conveyor by digital images, scan codes, or footprints.

The present invention is an apparatus for detecting and measuring density of parcels on a selected section of a conveyor surface, comprising or comprising a plurality of photo eyes for generating a table of sensing ranges. comprising or consisting of a device that Each photoeye has two outputs, each individually adjustable to obtain two different ranges. A plurality of photo eyes are arranged on a first side of a selected section of the feeder conveyor having a conveyor surface extending to a receive conveyor having a conveyor surface at a selected distance from a discharge end of the feed conveyor and a receiving end of the receive conveyor; and a second side surface of the side. The virtual encoder is programmable to generate pulses at selected intervals on the feed conveyor. The array includes a plurality of array elements, each array element representing one pulse of the virtual encoder defining a selected length of a selected distance. The programmable logic controller has an algorithm for calculating an average measured occupancy of the array that represents the fill rate of the receive conveyor.

A method of detecting and measuring parcel density at a selected section of a conveyor surface includes or consists of generating a table of sensing ranges using a plurality of photoeyes. Each photoeye has two outputs, each individually adjustable to acquire two different ranges. A plurality of photo eyes are arranged on a first side and an opposite second side of the selected section of the feed conveyor and the receive conveyor at a selected distance from the discharge end of the feed conveyor and the receiving end of the receive conveyor. will be installed. Pulses are generated at selected intervals along selected sections of the conveyor surface using a programmable virtual encoder. An array is created that includes a plurality of array elements, each array element representing one pulse of the virtual encoder defining a selected length of a selected distance. The average measured occupancy of the array is calculated by determining the combination of blocked photoeye outputs when encoder pulses representing the occupancy of the receive conveyor occur with a programmable logic controller using an algorithm. The measured occupancy of the feed conveyor relative to the desired occupancy is compared to the receive conveyor. The speed ratio is calculated by dividing the desired occupancy by the measured occupancy. The speeds of the feed conveyor, the receive conveyor, or the feed and receive conveyors are adjusted to obtain the desired occupancy of the receive conveyor.

In addition to distance sensing photoeyes, sensors may include opposing or left and right distance sensing photoeyes, vibration sensors, heat detection sensors, weight sensors, and smart light stacks in electrical communication with a PLC or computer.

It is an object of the present invention to include a photoeye to monitor packages along the collector conveyor, singulator conveyor, and sorter, in the merging area of the feed conveyor, to identify areas of low density, and to identify areas of low density of items in predetermined areas of the conveyor. The present invention provides a distance sensing conveyor package management system that controls activation and speed of selected conveyors to increase density.

It is an object of the present invention to detect a conveyor by comparing the free area with the area covered by packages on the conveyor based on digital data analysis of information from each photoeye monitoring the conveyor. To provide a distance sensing conveyor package management system that uses algorithms and software in a computer to calculate empty or unused areas on a conveyor.

The purpose of the invention is to assemble the data from the photo-eye and make selections within the system in order to fill large spatial areas of the collector conveyor with parcels such that the selected density of a particular area achieves 60% or more. An object of the present invention is to provide a distance sensing conveyor package management system in which a photoeye is interfaced with a computer that outputs a speed signal for a feed conveyor.

It is an object of the present invention to provide a distance sensing conveyor package management system that determines the percentage of surface area of collector conveyors, singulator conveyors, and other conveyors covered by packages, parcels, bags, envelopes, boxes, or other articles. That's true.

It is an object of the present invention to provide a distance sensing conveyor package management system that counts and identifies the number of items contained on a conveyor.

Distance sensing conveyor package management for identifying packages, parcels, or other items on a searched conveyor, or for identifying packages, parcels, or other items by their digital images or footprints The goal is to provide a system.

It is an object of the present invention to provide a distance sensing conveyor package management system that regulates input flow to a conveyor system. Photo eyes are placed at each input source to the collector conveyor and allow control of the speed of the respective input conveyor relative to the speed of the collector conveyor to maximize the flow of packages through the system.

The object of the invention is to force the packages to one side of the collector conveyor through friction, inclined rollers, belts or inclined surfaces so that a subsequent feed conveyor can remove these packages already present on the collector conveyor. To provide a distance sensing conveyor package management system that allows packages to be added to horizontal vacant areas.

It is an object of the present invention to provide a distance sensing conveyor package management system that recognizes the number of objects, the average size of objects, and the area utilization of the conveyor.

It is an object of the present invention to provide a vision-based system used to determine surface area coverage of singulator devices.

It is an object of the present invention to provide a vision-based system used to count the number of items contained on a conveyor.

It is an object of the present invention to provide a vision-based system used to regulate input flow to a conveyor system. A photoeye is placed at each input flow source, allowing control of each input with respect to the maximum allowed input flow into the system.

It is an object of the present invention to provide a vision-based system that recognizes the number of objects, the average size of objects, and the area utilization of a conveyor.

It is an object of the present invention to provide a distance sensing system for determining the sufficiency of the accumulation area of a conveyor system, and more specifically the sufficiency of a parcel singulator.

The aim of the invention is to optimize the singulator to cover the maximum amount of surface.

It is an object of the present invention to connect a photo-eye, a computer processor, and an Ethernet, WiFi, Bluetooth®, and other computer-based visual aid to phones, tablets, laptop computers, and other visual aids that are capable of communicating with Bluetooth® and computer systems. The present invention provides a visual-based flow management system that includes an interface for defining, controlling, and integrating conveyor control systems through other smart electronic devices such as equipment.

The present invention uses different sensing and detection methods to determine the one-dimensional linear, two-dimensional area, or three-dimensional volume of parcel flow density at selected sections of the feed and receive conveyors, and It relates to the field of adjusting a conveyor speed ratio proportional to the ratio of desired density to current density in order to increase the density or volume of parcels in a selected area.

The present invention includes a novel method for managing bulk parcel flow with a distance sensing management system. The method includes or consists of the following steps. Selecting a transition zone between a feed conveyor and a receive conveyor, each having an independent drive motor. Selecting a photoeye field of view for the selected transition zone. A step of specifying an IP address for each photo eye. Setting the speed of the inline feed conveyor to achieve the desired conveyor area utilization on the downstream receiving conveyor. Here, V is the velocity (velocity of the conveyor), DO is the desired occupancy, RCO is the receiving conveyor occupancy, and FCO is the feed conveyor occupancy ( The occupancy rate includes the area of the conveyor, the volume of the conveyor, or the density of the conveyor. Step of selecting the percentage of photoeye field of view. Step of selecting the percentage of the feed conveyor occupancy definition zone. Selecting the desired occupancy percentage after merging. Feeding the parcels into the occupancy defined zones of the receiving conveyor. Conveying the parcel toward the desired occupancy zone at the selected location. The step of merging the parcels at the transition section between the feed conveyor and the receive conveyor.

Apparatus and methods used to transport parcels and control the speed and direction of parcels on a conveyor are disclosed in U.S. Application No. 1, filed May 11, 2018, for Vision-Based Conveyor Package Density Management System. No. 15/977,244, issued October 1, 2019, in Applicant's U.S. Pat. No. 10,427,884, Applicant's co-pending Offload, Typing, and Item Separation System 16/189,014, filed Nov. 13, 2018, both of which are incorporated herein by reference in their entirety. Applicant's previous patents disclose camera-based visual density management systems. On the other hand, the present invention provides a more economical alternative based on distance sensing photo-eyes to measure parcel density and position as opposed to cameras.

Other objects, features, and advantages of the invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings.

A better understanding of the invention may be obtained by reference to the following description in conjunction with the accompanying drawings. In the drawings, like numbers indicate like parts.

Top view showing the conveyor surface with opposing distance sensing photo eyes installed at selected intervals on each side of the conveyor section near the exit end to generate a table of sensing or detection ranges Sensors with analog output when the actual distance of the sensed parcel from the end of the belt is known and distance sensing photoeyes on both sides of the belt are used to cancel the effect of parcels aligned to one side. Diagram showing the density measurement method using a distance sensing photo eye that outputs the actual analog distance using Diagram showing the architecture of distance sensing photo-eye for IO link-based areas On the downstream conveyor, the speed of the inline conveyor includes the percentage of the photoeye field of view, the percentage of the feed conveyor's occupancy-defining zone, the percentage of the receive conveyor's occupancy-defining zone, and the percentage of the desired occupancy after merging. 1 is a perspective view illustrating the photoeye field of view of the bulk parcel flow management system of the distance sensing based conveyor package management system according to the present invention configured to achieve a desired conveyor area utilization of A system in which rollers and belt conveyors utilize independent motors for conveying, placing, and separating parcels, conveyor area utilization, and distance sensing photo eyes located at selected conveyor flow entry points. 1 is a perspective view showing a feed conveyor, a receive conveyor and a singulator of a section of a conveyor system applying a linear parcel singulator, where the parcel counting principle utilized allows for efficient control of the singulator or other sorting device; FIG. Each one of the plurality of distance sensing photo eyes provides a field of view for defining the feed conveyor occupancy zone and the receive conveyor occupancy at the transition point of the upstream conveyor and downstream conveyor merging. Diagram showing the field of view of the distance sensing photo eye in the transition section Perspective view showing the field of view for detecting both the inclined roller section of the conveyor and the belt section of the parallel adjacent recirculation belt The rate of speed of the conveyor is determined based on the occupancy defined zone of the receive conveyor, the occupancy defined zone of the feed conveyor, and the photo-eye sensing range of the intersection based on the desired occupancy after merging. Top view showing the merging of the lateral transport feed conveyor with the intersecting collector conveyor, configured to achieve the desired conveyor area utilization in the downstream portion of the A trailer dock to sorter that includes a control system that adjusts multiple individual inputs based on conveyor sufficiency at various locations, where the speed of the conveyor is adjusted as a function of the singulator sufficiency and the occupancy entering just before the singulator. Schematic diagram showing distance sensing parcel density flow management system applied to bulk supply system to Create a receive conveyor occupancy zone and a feed conveyor occupancy zone in the monitoring configuration window, each one of which can be resized, dragged together, moved individually to different positions, or overlapped. Diagram shown Overhead view showing the PhotoEye distance sensing parcel flow management system with recirculation loop from the trailer unload feed conveyor to the singulator Diagram showing a feed conveyor including a modular section and a photoeye distance sensing array at each conveyor intersection Top view showing packages advancing on a feed conveyor parallel to the collector conveyor A top view showing packages advancing on a feed conveyor parallel to the collector conveyor of the conveyor shown in FIG. 13, with sections of the collector conveyor being controlled to form spaces for receiving articles conveyed by the feed conveyor. 14 is a top view showing packages advancing on a feed conveyor parallel to the collector conveyor of the conveyor shown in FIG. 13, with articles conveyed by the feed conveyor lined up in the receiving section of the collector conveyor; FIG. 14 is a top view illustrating a package advancing on a feed conveyor parallel to the collector conveyor of the conveyor shown in FIG. 13, with articles conveyed by the feed conveyor being fed to a position ahead of a plurality of articles being conveyed on the collector conveyor; FIG. 14 is a top view showing a plurality of packages advancing on the collector conveyor of the conveyor shown in FIG. 13, where the angled feed conveyor and the lateral feed conveyor are controlled to insert the packages into open areas of the collector conveyor; FIG.

According to the present invention, different sensing and detection methods are used to determine the one-dimensional linear, two-dimensional area, or three-dimensional volume of parcel flow density at selected sections of the feed and receive conveyors; A distance sensing parcel flow management system adjusts conveyor speed ratios proportional to the ratio of the desired density to the current density to increase the density or volume of the parcels in the selected area. provided.

The terminology used herein is for the purpose of particularly describing exemplary embodiments only and is not intended to be limiting. As used herein, the singular forms "a," "an," and "the" may be intended to include the plural forms as well, unless the context clearly dictates otherwise. The terms "comprises," "comprising," "including," and "having" are inclusive and therefore refer to the mentioned features, integers, steps, operations, elements. , and/or components, but does not exclude one or more other features, integers, steps, operations, elements, components, and/or groups thereof. The method steps, processes, and operations described herein should not necessarily be construed as requiring their performance in the particular order discussed or described, unless the order of performance is specifically specified. It's not like that. It is also to be understood that additional or alternative steps may be employed.

An element or layer is “on,” “engaged to,” “connected to,” or “coupled with” another element or layer. When referred to as "coupled to", it may also refer to being directly on, engaging, connected to, or bonded to another element or layer. , or there may be intervening elements or layers. On the other hand, an element may be "directly on," "directly engaged on," or "directly connected to another element or layer." ), or "directly coupled on," there may be no intervening elements or layers present. Other words used to indicate relationships between elements should be interpreted similarly (e.g., "between" vs. "directly between" and "adjacent"). ” vs. “directly adjacent,” etc.). As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Terms such as first, second, third, etc. are used herein to describe various elements, components, regions, layers, and/or sections; , layer, and/or section should not be limited by these terms. These terms may only be used to distinguish one element, component, region, layer or section from another region, layer or section. As used herein, terms such as "first," "second," and other numerical terms refer to order ( It does not imply any sequence or order. Thus, a first element, component, region, layer, or section discussed below may be a second element, component, region, layer, or section without departing from the teachings of the exemplary embodiments. Sometimes called a section.

For ease of explanation, the terms "inner," "outer," "beneath," "below," and "lower" are used herein. ), "above," and "upper" describe the relationship of one element or feature to another, as illustrated. can be used to Spatially relative terms may be intended to encompass different orientations of the device in use or operation in addition to the illustrated orientation. For example, when the device in the figures is turned over, elements labeled "below" or "beneath" other elements or features will appear "above" the other elements or features. ” Thus, examples of the term "below" can encompass both the above and below directions. The device may be oriented in other directions (rotated 90 degrees or in other directions) and the spatially relative descriptors used herein should be interpreted accordingly. be.

As used herein, the term "about" is reasonably understood by one of ordinary skill in the art to refer to slightly above or slightly below, within ±10%, the recited value. can be done.

As used herein, the term "parcel" includes an article, envelope, mail, package, bag, drum, box, or irregularly shaped item or container to be transported.

As used herein, the term "range sensing" refers to a photo eye, camera, video photo eye, scanner, laser, selected light transmittance frequency or wavelength, or other pixel sensing and and/or one or more imaging devices, including digital imaging devices (collectively referred to as photoeyes).

The invention will be explained in more detail below with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. However, this invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numerals indicate like elements throughout.

According to the present invention, a parcel flow management system based on a density-based distance sensing detection system that recognizes belt area utilization and parcel counts is provided.

The parcel flow management system comprises or consists of a density-based detection system that recognizes conveyor surface area utilization and parcel counts. Detection system sensors are placed at selected flow entry points across the conveyor. The control algorithm requires knowledge of the individual items, the speed at which the individual objects pass, and the area utilization of the conveyor surface to increase the conveyor surface and control crowding. Average parcel size may be considered as well. The detection package management system may also identify, locate, or track packages, parcels, or other items on the conveyor at selected locations on the conveyor through its measurements.

According to the present invention, a collector "receive" conveyor includes a programmable logic controller or computer, a sensor for detecting parcels or packages, and separate sections of the conveyor that are individually driven by separate motors having separate speed controllers. A density-based detection system conveyor package management system is provided comprising, consisting of, or consisting essentially of. A selected section of the collector conveyor has means such as a low friction conveyor surface, such as an angled roller, or a high friction conveyor surface that can urge the packages onto the selected side of the collector conveyor. The plurality of feed conveyors include separate sections of the conveyor that are individually driven by separate motors with separate speed controllers. Distance detection sensors measure the area, volume, or density of items on the conveyor surface leading to the merging area of each feed conveyor with the collector conveyor. The speed of the feed conveyor and the collector conveyor leading to the merging area of each collector conveyor is measured. A control program in the PLC or computer adjusts the speed of the sections of the collector conveyor and the speed of the feed conveyor based on the amount of free space on a given collector section compared to the footprint of the package on the approaching feed conveyor. You can control the speed of the sections. A singulator conveyor may be incorporated within a conveyor system and fed by a collector conveyor.

A typical feed conveyor or collector "receive" conveyor includes one or more separate sections of the conveyor that are individually driven by separate motors with separate speed controllers. A selected one section of the collector conveyor may have a low friction conveyor surface, such as an angled roller and/or a belt, arranged in a configuration that can urge packages to the selected side of the receive collector conveyor. may include high friction conveyor surfaces such as The multiple feed conveyor surfaces may include separate sections of the conveyor that are individually driven by separate motors with separate speed controllers.

Detection range devices monitor the area of the collector conveyor leading to the merging area of the respective feed conveyor with the collector conveyor; monitor the area. A bulk parcel flow management system determines the "velocity" of a feed conveyor and/or a collector "receive" conveyor, or a section of a collector "receive" conveyor and/or a section of a feed conveyor, based on its availability. Includes a programmable logic controller or computer as a control program in a computer or PLC that can be controlled based on space complexity. A given collector section is compared to the footprint of the package on the approaching feed conveyor. Pulses are generated at intervals selected by calculations by the photo-eye and virtual encoder to generate an array that determines the measured occupancy as a percentage of the fullness of the parcels on the feed conveyor and/or the collector "receive" conveyor. .

For example, the current FDXG request for the control conveyor for the selected area and speed is 7,500 parcels per hour for 10 minutes, 2 (1 minute) slices at 8250 parcels per hour, (7500/12150 = 0.62 = 62% , efficiency in a 10-minute test). The present invention provides a means to control the area utilization of the available conveyor surface to obtain efficiencies of up to 75%, equivalent to 9,375 parcels per hour, for the same conveyor. Furthermore, for a distance sensing conveyor package management system with area utilization according to the present invention, a 15% increase results in an increase of 8,625 parcels per hour.

Distance sensing devices are placed at selected discrete input points and communicate by wire or wirelessly with a PLC or computer containing process control algorithms to determine incoming flow density, both in terms of belt utilization and throughput ratio. recognize. These measures can be used for changes that reduce parcel input flows and can require stopping of feed lines if the flow becomes too sparse or too dense. Similarly, recognizing a lack of flow, the selected input conveyor or input conveyor speed can be increased.

The detection device can be arranged to look at the singulator surface and is used in a similar matter to evaluate buffer capacity utilization, primarily based on area coverage recognition. This feedback is used to dynamically adapt the feedline operation. The use of Web Cams may provide additional benefits in terms of system control room visibility and recording. Variations in parameters used to tune the system can be evaluated in a more efficient manner. Blockages and other system problems are better recognized.

A plurality of distance sensing photo-eye detection devices in communication with a computer-based conveyor package management system detect the number and size of packages representing a predetermined area of the feed conveyor, collector conveyor, and optionally singulator conveyor and sort conveyor of the package handling system. including. Data is collected and analyzed to measure the available area or space of the conveyor and its density of packages to maximize the desired density of packages on the selected conveyor. The number of feed conveyors providing packages and the speed of each conveyor are controlled as a function of the occupancy on the collector or just before the singulator. The computer provides conveyor surface package density information to a conveyor speed controller to induce packages from one or more feed conveyors to a collector conveyor. Packages are detected across the area, volume, or density of the conveyor surface, and the chosen conveyor speed places the packages in the optimal space, maximizing the density of packages on the conveyor and the throughput of the system. Thus, the conveyor area is controlled to be filled in the most efficient manner that minimizes the number of conveyors required for the system. When the computer determines that there is enough space on one of the conveyor belts, for example the collector belt, the computer adds the package by having the feed belt add the package to the space or empty area on the collector belt. Instruct the controller to do so.

An algorithm is used to calculate the "measured occupancy". The sensing distance thereby represents a percentage of belt coverage. Once the "measured occupancy" of the conveyor is calculated, it is compared to the "desired occupancy" of the conveyor surface area to determine the speed ratio of the downstream conveyor. The "Speed Ratio" is the desired occupancy divided by the measured occupancy, and the speed commanded to the conveyor is determined by the following equation: where (FPM) is measured in feet per minute.

Current conveyor speed (FPM) = downstream speed (FPM) * speed ratio ** power factor

Using different sensing methods to determine the one-dimensional linear, two-dimensional area, or three-dimensional volume of flow density on a conveyor, the desired density relative to the current density can be used to improve conveyor system performance and throughput. Adjust the conveyor speed ratio proportional to the density ratio.

The distance sensing conveyor package management system for measuring and controlling the density of parcels on a conveyor of the present invention uses different sensing and detection methods to detect flow density on selected sections of a feed conveyor and/or a receive conveyor. Determine the degree of one-dimensional linear, two-dimensional area, or three-dimensional volume to the ratio of desired density to current density to increase parcel density or volume in selected areas of the receiving conveyor. Adjust the proportional conveyor speed ratio.

In the two-dimensional discrete distance measurement method, a SICK WTT190L PhotoEye is used to generate a table of sensing ranges. Each photoeye has two outputs, each of which can be adjusted independently to obtain two unique ranges. As shown in FIG. 1, photo eyes are installed on each side of the conveyor section at a selected distance of approximately 5 feet from the exit end of the conveyor. Optionally, multiple photoeyes may be installed in banks or arrays.

As shown in FIG. 1, a first side 361 of the conveyor having a width of 61 inches includes a photo eye 351 that measures up to 13 inches across the conveyor, and an opposite side of the opposite second side 362 of the conveyor. The PhotoEye 362 measures distances up to 48 inches. The photoeye 353 on the first side of the conveyor measures up to 25 inches across the conveyor, and the opposite photoeye 364 on the opposite second side of the conveyor measures up to 36 inches. The photoeye 355 on the first side of the conveyor measures up to 37 inches across the conveyor, and the opposite photoeye 366 on the opposite second side of the conveyor measures up to 24 inches. The photoeye 357 on the first side of the conveyor measures up to 49 inches across the conveyor, and the opposite photoeye 358 on the opposite second side of the conveyor measures up to 12 inches.

The virtual encoder is programmed to generate pulses to the conveyor section at selected intervals, such as every two inches of belt movement. The array is created to represent the last 5 feet of the feed conveyor section plus an additional 5 feet, or 120 inches, on the receive collector conveyor or downstream conveyor section. If each element of the array represents a 2 inch section or one pulse of the virtual encoder, the total number of elements of the array at the time of conveyor transition is 60.

Depending on the combination of photoeye outputs that were blocked when the encoder pulse occurred, a "measurement occupancy" value is entered into the current array element. "Measurement Occupancy" is the percentage of sufficiency, where 0 indicates no empty belt or blocked photoeyes, and 100 indicates all photoeyes are blocked. The photoeye is re-evaluated with each encoder pulse and the result is input into the current array position. The overall measured occupancy for a 10-foot section of the conveyor (5 feet at the exit of the current belt and 5 feet at the entrance of the downstream belt) is summed over all values in the array and divided by the total number of elements in the array. required by.

The following table describes how the combination of blocked photoeyes results in the proper measurement occupancy input to the array.

As shown in Table 1, the state of the first left photo-eye is resolved first. The second right photoeye can then be solved to obtain the percentage of sufficiency with the encoder pulses expressed in the table values. Once a suitable combination is found, the algorithm terminates and the resulting value is placed in the current array element. The algorithm stores the last six values, sums them all up, and then divides by the total number of elements in the array to obtain the average measured occupancy expressed as a percentage ranging from 0 to 100. Note that "n/a" in the above table means that the photo eye cannot exist in a state where the range of the photo eye is adjusted as shown in the figure.

Once the measured occupancy of the belt is calculated, it is compared to the "desired occupancy" of the belt and then calculated to determine the speed ratio of the downstream belt. "Desired occupancy" is a configurable parameter. A range of 30% to 40% is assumed, but the final value will need to be determined in the field. The speed ratio is the desired occupancy divided by the measured occupancy. Therefore, if the desired occupancy is found to be 30% and the measured occupancy is 70%, the speed ratio is 30/70 or 0.429. The speed commanded to the belt is determined by the following equation.

Current conveyor speed (FPM) = downstream speed (FPM) * speed ratio ** power factor

(PowerFill 2D using IO-Link based analog distance sensing range)
The following example of a density measurement method uses a BALLUFF BOD0020 PhotoEye that outputs actual analog distance. By using a sensor with an analog output, the true distance of the sensed parcel from the end of the belt can be determined. Distance sensing photo eyes are still required on both sides of the belt to cancel the effect of parcels aligned to one side. The sensing distance is set to the maximum value of the conveyor width shown in FIG. 2, with LPE1 being 364 and RPE1 being 363.

A virtual encoder is programmed for the conveyor section to generate pulses at 2 inch intervals of belt movement. The array is created to represent the last 5 feet of the conveyor section plus an additional 5 feet, or 120 inches, of the downstream conveyor section. With each element of the array representing two inches or one pulse of the virtual encoder, the total number of array elements at the conveyor transition is 60 array elements.

An algorithm that calculates a "measured occupancy" is calculated and compared to a "desired occupancy" of the belt that can be calculated to determine the speed ratio of the downstream belt. The sensing distance represents a percentage of the belt or "conveyor surface area" coverage. Parcels detected at 60 inches will get a percentage close to 0%, while parcels detected at 1 or 2 inches will get a percentage close to 100%. In order to obtain a "measured occupancy," the combination of distances sensed by both photoeyes must be used to generate an accurate occupancy across the belt. This value is calculated for each virtual encoder pulse and placed in the overall measurement occupancy array. The photoeye is re-evaluated with each encoder pulse and the result is input into the current array position. The overall measured occupancy of a 10-foot section of the conveyor (5 feet at the exit of the current belt and 5 feet at the entrance of the downstream belt) is determined by summing all values in the array and dividing by the total number of elements in the array. It is determined by

Once the measured occupancy of the belt is calculated, it can be compared to the "desired occupancy" of the belt and then calculated to determine the speed ratio of the downstream belt. "Desired occupancy" is a configurable parameter. It is assumed to be in the range of 30% to 40%, but the final value will need to be determined in the field. The speed ratio is the desired occupancy divided by the measured occupancy. Therefore, if the desired occupancy is found to be 30% and the measured occupancy is 70%, the speed ratio is 30/70, or 0.429. The speed commanded to the belt is determined by the following equation.

Current conveyor speed (FPM) = downstream speed (FPM) * speed ratio ** power factor

As previously mentioned, power factor can be used as a configurable parameter in the above equation to set how fast the current belt should be for larger corrections. I can do it. A larger power factor means more aggressive correction. The power factor can be set to 1 for the two-dimensional region "2D" of PowerFill.

For example, a sensing method for determining flow density in a density defined by a linear region "1D", a two-dimensional region "2D", or a volume "3D" may be used to determine the ratio of the desired density to the current density. Determine and adjust the conveyor speed ratio proportional to .

The analog signal obtained from PhotoEye is IO-Link, so the main PLC obtains distance information from PhotoEye via Ethernet. Figure 3 shows the architecture of IO-Link-based PowerFill 2D. The IO-Link 365 device includes a left distance sensing photoeye 366, a right distance sensing photoeye 367, an optional smart light stack 368, an optional vibration detection sensor 369, and an optional thermal detection sensor 370. It is contemplated that other sensors known in the art may be linked as well.

The IO-Link master has the following features useful for PowerFill 2D applications:
The IO-Link master is a field mount device. The sensor connects directly to the unit via a standard 5-pin Euro-style cordset. It connects to the PLC via Ethernet. The ability to connect to other IO-Link input devices such as temperature or vibration sensors can be implemented. Like the smart light described above, it is possible to realize the function of connecting to an IO-Link output device. Smart lights can be configured with multiple colors, multiple flashes, or static configurations. The sensor has a diagnostic function via IO-Link to the PLC, and can display the photo eye that has become dirty on the HMI (and smart light). Configuration parameters for configuring the device (such as range and output unit) are stored in the PLC, so when the device is replaced, no configuration is required for device replacement.

A parcel flow management system consists of multiple conveyor modules or sections with belts and/or conveyor rollers for transporting and separating items such as envelopes, mail, packages, bags, drums, boxes, or irregularly shaped items. comprising or comprising a density-based detection system compatible with a conveyor system having a plurality of sections 10 including a conveyor system having a plurality of sections 10; As shown, linear parcel singulator 8 and recirculation conveyor 14 are in flow communication therewith. A plurality of photo eyes provides a view of selected occupancy-defined zones, such as a transition area 70 or a transition point for the confluence of articles from one conveyor to another. Individual motors drive conveyor modules or sections to form zones that can be accessed by a particular photoeye via an assigned IP address.

At least one photoeye, camera, video camera, or other pixel detection and/or digital imaging device is placed at each separate input point to reduce incoming flow congestion, both in terms of belt utilization and throughput rates. It has a control algorithm to recognize the degree. These measures can be used to modify parcel input flows to reduce them, and may require stopping feed lines if the flows are too dense. Similarly, recognizing a lack of flow, the speed of the input conveyor can be increased.

A photo-eye positioned to look at the singulator surface is used in a similar manner to evaluate buffer capacity utilization, primarily based on area coverage recognition. This feedback is used to dynamically adapt the operation of the infeed line. Using a webcam provides an additional benefit in terms of system control room visibility. Variations in parameters used to tune the system can be evaluated in a more efficient manner. Blockages and other system problems are better recognized.

In one preferred embodiment, the distance sensing photoeye and computer-based conveyor package management system is capable of controlling the number of packages present on an infeed conveyor, collector conveyor, singulator conveyor, and/or sort conveyor of a package handling system. and a distance-sensing photo eye to monitor size. Photoeye data is used to measure the available area or space or volume on the conveyor to maintain the desired density of packages on the selected conveyor. The speed of the conveyor is controlled as a function of the occupancy on the collector or just before the singulator. A computer provides information to a conveyor speed controller to direct packages from one or more feed conveyors to a collector conveyor. The packages are detected by one or more photoeyes, and the conveyor speed and/or package or article speed selected maximizes the density or volume of packages in a given conveyor area and the throughput of the system, thus Controlled package placement minimizes the number of conveyors required for the system. When the computer determines that there is sufficient space on one of the conveyor belts, e.g., the collector conveyor, it causes the infeed belt to add packages by causing the infeed belt to add packages to the spaces or empty areas on the collector belt; The computer instructs the controller.

It is contemplated that a line scan photo eye with a single row of pixel sensors can be utilized with the present invention. The lines are continuously fed to a programmable controller, a programmable logic controller (PLC), or a computer that couples them together to generate an image. Multiple rows of sensors can be used to generate color images and increase sensitivity with time delay and integration (TDI). Conventionally, it has been extremely difficult to maintain stable light over a wide two-dimensional area, and industrial applications often require a wide field of view. Using a line scan photoeye provides uniform illumination across the "line" that the photoeye is currently viewing. This makes it possible to obtain clear images of objects passing through the photo eye at high speed, and it can be used as an industrial device for analyzing high-speed processes. Three-dimensional photo-eye systems that utilize one or more photo-eyes or other pixel detection devices and/or digital imaging devices can also be used to detect package height and determine volumetric density. .

A photoeye-based density measurement system recognizes and maximizes feed conveyor belt area utilization. A plurality of photo eyes may be placed at selected points on the receiving ends of the feed and receive conveyors. A computer with a control algorithm recognizes the area of the individual items, the footprint of the items and the rate at which the individual objects pass, and the area utilization of the feed conveyor. A distance sensing photoeye and computer-based conveyor package management system monitors and controls the speed of the feed conveyor based on the number and size of packages present on the feed conveyor. Information from the receive conveyor and collector conveyor or singulator conveyor and/or sort conveyor of the package handling system may also be used. Photoeye data is used to measure the available area or space or volume on the conveyor and maintain the desired density of packages on the selected conveyor. The speed of the conveyor is controlled as a function of the occupancy on the collector or immediately before the slide sort conveyor, singulator, or receive conveyor.

The distance sensing parcel flow management system 5 comprises or consists of a section 10 of a conveyor system. The plurality of photoeyes 20 are connected to at least one feed in conjunction with a singulator 8, a hold-and-release conveyor, an accumulator, and/or a strip conveyor typically downstream from the feed conveyor 11 and shown in linear alignment with the singulator 8. Parcels on a primary or main conveyor collector conveyor incorporating a conveyor 11 and one receiving conveyor 13 are detected. The conveyor utilizes rollers and/or belts, each unit powered by at least one independent motor and selected based on a selected operating ratio or desired occupancy of the selected conveyor or conveyors. Convey, place, and separate parcels at the same speed ratio. The degree of occupancy can thus be controlled on each conveyor independently of its upstream or downstream adjacent conveyors. The multiple conveyors of the conveyor system can be started, stopped, or sped up or down to increase the footprint for the multiple conveyors. Conveyor system section 10 utilizes independent motor-driven conveyor zones.

Conveyor system section 10 includes at least one feed conveyor 11 and a downstream receive conveyor 13. The speed of the selected in-line feed conveyor is set to achieve the desired conveyor area utilization on the selected downstream receive conveyor 13. The photo eye 21 is activated when the parcels are conveyed toward a desired occupancy zone 19 concentrated at a selected location after the transition section, zone, or point 70 where the feed conveyor 11 and the receive conveyor 13 meet. is used to indicate the field of view of the feed conveyor occupancy zone 15 set for a predetermined velocity V2 of parcels being fed to the occupancy definition zone 17 of the receive conveyor.

More particularly, as shown in FIG. 6, a plurality of photo eyes are shown focused on selected transition sections 70 of conveyor system section 10. The photo eye 21 focuses on the feed conveyor occupancy definition zone 15 and the receive conveyor occupancy definition zone 17, from the feed conveyor 11 to the receive conveyor 13, such as the receive conveyor collector conveyor 12 or other downstream conveyor. Provides a view of the portion of the conveyor system where the parcels move. Downstream photoeyes 22 and 23 focus on downstream occupancy zones at other transition points 72 and 73, respectively, within conveyor system 5. The speed ratios of the individual conveyors are set to achieve the desired conveyor area utilization in the concentrated desired occupancy zones.

Photoeye 20 can measure occupancy across multiple zones. As shown in FIG. 4, the occupancy of both inclined roller sections 16 of the conveyor is measured similarly to the recirculation belt section 14.

FIG. 8 shows a lateral transport feed conveyor 31 carrying articles 66 intersecting the stream of collector conveyor 12 at a 90 degree angle. Of course, the intersection angle is a matter of choice and may be any angle up to 90 degrees. Side feed conveyor 31 is shown feeding articles 67 to receive or collector conveyor 12. The speed of the side feed conveyor 31 is controlled to achieve the desired conveyor area utilization on the receive collector conveyor 12. The speed of conveyors 12 and 31 is determined by the photo at the selected location 65, including both the feed conveyor's occupancy-defining zone 15 and the receive collector conveyor's occupancy-defining zone 17 before the conveyors merge at the transition point 73. Determined by eye measurements. The desired post-merging occupancy zone 19 has increased density in the selected area after the articles have joined.

The distance sensing photoeye parcel flow management system 5 is applicable to bulk feed systems from the unloading point of goods from the trailer to the guided conveyor through a separate sorting process to the guided conveyor. As illustrated in FIG. , 47, 48, and 50 and the collector conveyor 12 is adjusted by the photo eyes 26, 27, 28, and 29, and the speed ratio of the confluence or inductive feed conveyors 44, 46, 47, 48, and 50 is adjusted by the photo eyes 26, 27, 28, and 29. A photoeye view at each transition point 73, 74, 75, 76 and 77 with the collector conveyor 12 is provided. The collector belt 12 may be dedicated to an off-road induction conveyor, or may flow from other sources such as a recirculation conveyor 14 from a sorting area with full output lanes. Inductive feed conveyors 44, 46, 47, 48, and 50 are adjusted as a function of the speed of collector conveyor 12 and the percent occupancy of articles on collector conveyor 12. An accumulator conveyor or accumulator 35 is located upstream of singulator 8 and downstream from collector conveyor 12 and may be utilized as a receiving conveyor. The movement of the feed and/or receive conveyor may be adjusted as a function of the accumulator conveyor 35 immediately in front of the singulator, in order to provide smooth feeding to the singulator 8, in the area of the conveyor occupied by the packages. Based on. The downstream singulator 8 has a singulator photo eye 32 that provides a field of view 319 of the goods on the singulator 8 and a field of view 329 of the goods that merges at the transition point 78 with the singulator 8 fed from the adjacent accumulator conveyor 35. and a photo eye 41 that provides.

A computer or microprocessor control system 500 controlling the vision-based bulk parcel flow management system adjusts multiple individual inputs based on singulator sufficiency. The conveyor speeds of feed conveyor 11, induction conveyors 44, 46, 47, 48, and 50, collector conveyor 12, recirculation conveyor 14, singulator 8, and accumulator 35 depend on the filling of the singulator and the incoming percent occupancy. controlled and adjusted as a function of

The distance sensing photoeye visual control system includes at least one pair of opposing smart photoeye modules 20 that are capable of processing distance sensing data, such as by zooming in or out, or by determining the optimal conveyor speed. By selecting a specific grid or area on the device, each photoeye can be adjusted to determine the distance across the conveyor within the defined zone. The smart photo eye module processes the distance sensing data and determines the percentage occupancy within the defined zone. The IP address of the photo eye is specified for each photo eye 20. For example, the photo eye may be programmed or configured to simply "right click" to define the photo eye's IP address. The Ethernet system provides a means to transfer signals to a computer via a command PC, PLDC, or VLC control system to calculate occupancy information and calculate the desired conveyor speed. The interface may be realized via a smartphone, tablet, laptop, smartwatch, standalone terminal, and/or network. The configuration software provides a convenient interface for configuring control zones and entering control parameters. A separate photoeye IP address is assigned to each photoeye of the vision system.

The vision-based bulk parcel flow management system opens a configuration window for defining "monitoring" parameters and provides a means for defining zones where occupancy is measured at any time for any PhotoEye occupancy-defined zone. include. FIG. 10 is a monitoring configuration window showing receive conveyor occupancy zones and feed conveyor occupancy zones, each resized, dragged together, or moved individually to different positions or overlapping. shows. A series of photoeyes for a particular transition point are selected and utilized to provide a view of the feed conveyor occupancy zone 15 and the receive conveyor occupancy zone 17 to determine conveyor area utilization and article counts. The feed conveyor occupancy zone 15 can be resized according to selected parameters on the computer, smartphone or tablet screen by simply adjusting the size of the screen area. Furthermore, the occupancy zones of the receiving conveyor can be dragged and resized in the same manner. The occupancy ratio is calculated according to the selected area to achieve the highest density of articles on the conveyor.

Set for a predetermined speed V2 of the articles fed to the singulator conveyor according to the occupancy defined in zone 17, which is usually a transition point but can be any area or zone of the selected conveyor or article processing site. A photo eye area is utilized to show the field of view of the feed conveyor occupancy zone 15 that has been filled. The photo-eye based vision system 5 recognizes belt area utilization and article counts. The vision system photoeye 20 is typically located at the flow entry point of the collector conveyor 12 and at the singulator 8 . The control algorithm requires knowledge of the speed at which individual items and objects pass, and the area utilization of the collector belt. Average article size and shape may be considered as well. A photoeye and computer-based conveyor package management system includes a photoeye that monitors the number and size of packages present on the infeed conveyor, collector conveyor, singulator conveyor, and sorting conveyor of a package handling system. The photo eye data is used to measure the available area or space on the conveyor to maintain the desired density of packages on the selected conveyor. It is even possible to trace and/or trace individual items by their labels, codes, or physical characteristics from their receipt from unloading trucks and unloading docks to the point of delivery vehicles. be.

(Example 1)
As shown in FIG. 11, packages are transferred from the cargo carrier to selected inductive feed conveyors 44, 46, 47, 48, and 50 in flow communication with collector conveyor 12, which is configured in modules in sections of conveyors 120-134. be taken off. For example, inductive feed conveyor 50 intersects and supplies articles to collector conveyor section 121, inductive feed conveyor 48 intersects and supplies articles to collector conveyor section 124, and inductive feed conveyor 47 intersects and supplies articles thereto. Feed conveyor 46 intersects with collector conveyor section 127 to supply articles thereto, feed conveyor 46 intersects with conveyor section 129 to supply articles thereto, and feed conveyor 44 intersects with collector conveyor section 132 to supply articles thereto. supply. Recycle or recirculation conveyor 14 intersects and supplies articles to conveyor section 134.

According to FIG. 12, the collector conveyor 12 starts with a first feed conveyor 50 and extends to an accumulator 35 and/or singulator 8 intersecting a selected number of inductive feed conveyors 44, 46, 47, 48 and 50. The recycle conveyor 14 also supplies articles to an accumulator 35 or other conveyor that intersects the collector conveyor 12 before the singulator conveyor 8. The inductive feed conveyor includes a selected number of modules or sections. For example, as shown, sections 502, 504, 506, 508, 510, and 512 are sections of an inductive feed conveyor that include at least one transition point. The speed of the selected guided feed conveyor is set to achieve the desired conveyor area on the selected downstream receive conveyor 13. The parcels are concentrated in a desired occupancy zone 19 at a transition section, zone, or selected location after the respective points 200, 210, 220, 230, and 240 where the inductive feed conveyor and receive collector conveyor 12 meet. When conveyed, the photo eyes 20, 21, 22, 23, and 24 are placed in the occupancy zone 15 of the induction feed conveyor set for a predetermined velocity V2 of the parcels being fed into the occupancy zone 17 of the receiving conveyor. It is used to indicate the field of view. Feed conveyors 44 , 46 , 47 , 48 , and 50 also include modules or conveyor sections having designated motors that operate individually to increase or decrease the density of articles on collector conveyor 12 .

Each conveyor or conveyor section is driven by a separate variable speed motor. This allows the speed of the individual sections of the conveyor 50 to space out or concentrate the packages in a given area in the desired manner, depending on the optimum flow rate handled by the accumulator 35 or the singulator 8. can be raised or lowered. For example, if a large gap 90 is detected between two particular packages, the speed ratio of the section of the conveyor between those packages is increased to narrow the gap between those packages. As best shown in FIGS. 13-16, the articles on the feed conveyor intersect with the collector conveyor and packages 89 are inserted from the feed conveyor 11 into the receive/collector conveyor 12 containing a plurality of packages 81-88. , a method for inserting a package 89 into a gap 90 between other packages on a moving collector conveyor 12 is sequentially described. As shown in FIG. 17, a plurality of packages 91 are conveyed on the collector conveyor 12. Angled feed conveyor 92 and vertical lateral feed conveyor 93, each intersecting collector conveyor 12, carry parcels 89 such that the speed of both feed conveyors 92 and 93 is higher than that already present on collector conveyor 12. The parcel 89 is controlled to be inserted into the gap formed between the parcels 91 of.

The distance sensing photoeye percell flow management system includes multiple feed conveyors in line or at up to a 90 degree angle to the receive conveyor, an optional recirculation conveyor 14, an optional accumulator, a sorting lane, and a sink. regulator conveyor 8. The video photoeye monitors the feed conveyor just before it joins the collector belt 12 in each monitoring area 200-250. Another video photoeye 32 monitors the area 319 containing the singulator conveyor 8. Photo eyes 26, 27, 28, 29, 30, and 32 monitor selected sections of conveyor 12 in front of the area where the infeed conveyor joins collector conveyor 12. Electrical cabinet 51 includes a video computer 500 that receives video input data from photoeyes 20-25 and 32. Electrical cabinet 52 contains speed controllers for the motors for all conveyors 44-50. The video computer can count individual packages and calculate the package size "area" based on information from the various photo eyes monitoring the conveyor.

The singulator conveyor 8 receives the randomly distributed packages and aligns them with respect to the movement of the conveyor. For an example of a singulator conveyor, see U.S. Pat. No. 14/121,829, incorporated herein by reference in its entirety.

Singulator conveyor 8 receives packages and articles, such as bags or envelopes, parcels, boxes, packages, mail, or other articles, from upstream conveyor 12. After singulator conveyor 8, the individual packages are sorted and sent to recirculation conveyor 14. The recirculation conveyor 14 conveys packages removed during the sorting process to the selected receive conveyor collector conveyor 12 for re-sorting at the singulator. The primary object of the present invention is to provide a steady flow of packages through the singulator conveyor 8 without clogging the collector conveyor 12 with package surges and slugs received from the upstream feed conveyor. to keep it fully supplied.

Singulator conveyor systems can handle randomly sized packages. Preferably, the packages on the feed conveyor are lined up. However, as the packages are unloaded from the trucks onto selected feed conveyors 44, 46, 47, 48, and 50, it is not uncommon for them to be irregularly spaced and randomly oriented. Unloading typically occurs in slags where large quantities of packages are unloaded in a short period of time.

For example, as best shown in FIG. 12, photoeye 30 monitors the area conveying occupancy zones of conveyor sections 122 and 123. In the occupancy zone area 210 monitored by the photo eye 21, if the density of packages in that area is low, the digital image data (pixels) are processed by the controller and the computer controls the conveyor 48 to move the collector conveyor section. Start, stop, slow down, or speed up the feed rate of packages on 124.

The package is conveyed downstream toward conveyor section 35 and passes through photoeyes 26, 27, 28, 29, 30, and 31 as the package passes through the transition section between conveyors and through subsequent photoeye occupancy zones. monitored by A computer program analyzes the overall load of the conveyor section on a pixel by pixel basis. Packages in a particular occupancy zone area are monitored by a photo eye and a digital image of the footprint size of the package is verified by video computer 500. The computer decides whether to maximize conveyor area depending on the sharing speed and downstream load. Video-based package management systems utilize the area of the entire conveyor assembly to control the flow of packages to singulators, separators, scanners, or processing sites. The speed of the conveyor is controlled as a function of the occupancy on the collector or just before the singulator. The computer provides information to a conveyor speed controller to direct packages from one or more feed conveyors to a collector conveyor. The package is detected by one or more photo eyes. The speed of the selected conveyor is controlled to maximize the density of packages on the conveyor and throughput of the system, and to place the packages in an optimal space that minimizes the number of conveyors required by the system. . When the computer determines that there is sufficient space on one of the conveyor belts, e.g. collector belt 12, the computer causes the feed belt to add packages 89 or packages to spaces 90 or empty areas on collector belt 12. A signal is sent to the controller to add package 89 or a package.

As the density of packages decreases in the transition zone between the feed conveyor and the collector conveyor 12, gaps are formed between the packages, thereby increasing the desired flow rate of packages to the collector to maximize the throughput of the singulator. The speed ratio of the selected feed conveyor is increased to maintain .

This control scheme prioritizes any selected conveyor. For example, if the collector conveyor 12 tends to be empty or have a smaller dense load, the first feed conveyor at the beginning of the collector conveyor 12 may be prioritized. Therefore, packages on the first feed conveyor typically have more free space. Selected sections of the collector conveyor 12 may be slowed down or even stopped, if necessary, to allow the latter feed conveyor to unload. Additionally, the collector conveyor 12 may be slowed down or stopped to force more packages from the feed conveyor and force additional articles onto the collector conveyor 12 to fill the area of the collector conveyor.

The package flow management control system 5 maximizes the throughput of packages to the singulator conveyor and sorting system and maximizes the utilization of the area on the collector conveyor or accumulator before the singulator 8. The other conveyors in the conveyor system are controlled based on the maximum capacity of the singulator, which is determined by a constant speed ratio, rather than the average surge capacity. The increased efficiency allows the number of conveyors required and the area, width, and/or length of the conveyors within the system to be minimized to achieve the desired throughput with maximum efficiency.

Video computer 500 utilizes multiple photoeyes to monitor occupancy zones of selected areas of the conveyor following the singulator or isolated process. The computer compares the amount of free space on the selected conveyor and compares it to the size of the package on the feed conveyor. If there is adequate space, the feed conveyor will transport the packages. The amount of room a given package requires is determined by the programmer. For example, a program may require that the amount of space on the collector conveyor be 1.5 times or twice the footprint of a given package, depending on the orientation of adjacent items. Changes in the speed ratios of the various conveyors are also controlled by a video computer to maintain a sufficient supply of the singulator conveyor. The computer sends speed control signals to speed controllers in all conveyor sections to adjust package throughput.

The above detailed description is provided primarily for clarity of understanding and no unnecessary limitations should be taken therefrom. Modifications will be apparent to those skilled in the art after reading this disclosure and may be made without departing from the spirit of the invention and the scope of the appended claims. Therefore, the invention is not intended to be limited by the specific examples presented herein. Rather, what is intended to be covered is within the spirit and scope of the following claims.

Claims (12)

a feed conveyor and a receive conveyor, each having an independent drive motor;
the feed conveyor including a distance sensing measurement region at a distal discharge end adjacent to the receive conveyor;
a receiving conveyor comprising a distance sensing measurement region at a distal receiving end adjacent to the feed conveyor; and calculating a feed conveyor density of articles on the feed conveyor as a percentage of the occupancy of the feed conveyor; to calculate the receiving conveyor density of articles as a percentage of the receiving conveyor density in the transition zone across the transition zone including the conveyor face of the measuring area of the feed conveyor and the conveyor face of the measuring area of the receiving conveyor. a distance sensing photoeye array in communication with a virtual encoder and signal generation and detection means extending from the
The speed of the conveyor is determined based on the signal received from the distance sensing photoeye that identifies gaps between the articles on the receive conveyor of sufficient space for the insertion of additional articles from the feed conveyor. ) and a computer means for controlling the movement;
Equipped with
The speed (velocity) of the feed conveyor, the speed (velocity) of the receive conveyor, or the speed (velocity) of both the feed conveyor and the receive conveyor are determined by the area occupancy of the conveyor on the receive conveyor. controlled at a selected rate (velocity) to achieve a desired density based on a percentage;
Distance sensing photo-eye array device. Conveyor speed or velocity is a function of the occupancy (volume, area, or density) of the articles on the selected conveyor immediately preceding the slide sorter, collector conveyor, singulator conveyor, or receive conveyor. controlled using a control algorithm that is aware of the incoming flow occupancy (volume, area, or density), both in terms of belt utilization and throughput rate to control the incoming flow of the
The distance sensing photo-eye array device according to claim 1 . Further, at least one pair of opposing distance sensing photo eyes, at least one camera, and at least one pixel detection device disposed at the input point of the receiving conveyor, collector conveyor, singulator conveyor, sorting conveyor, and combinations thereof; at least one digital imaging device, and combinations thereof;
The distance sensing photo-eye array device according to claim 1 . the computer includes a programmable logic controller having an algorithm for calculating an average measured occupancy of the distance sensing photoeye array indicative of a percentage of occupancy of the receive conveyor;
The photo-eye array device according to claim 1 . the computer calculates a selected maximum percentage of occupancy of the receive conveyor based on the speed ratio of the feed conveyor;
The photo-eye array device according to claim 1 . the distance sensing photoeye array includes a plurality of array elements, each array element indicative of one pulse of the virtual encoder defining a selected length of the distance sensing measurement area;
The photo-eye array device according to claim 1 . In addition, it supports Ethernet , WIFI, Bluetooth , and other smart electronic devices, including smartphones, computer tablets, laptop computers, and visual aid computer-based devices that can communicate with computer systems. a computer interface for defining, controlling, and integrating a computer control system of said conveyor via;
The photo-eye array device according to claim 1 . selecting a transition zone between a feed conveyor and a receive conveyor each having independent drive means;
selecting a measurement area of a distance sensing photo-eye array in the selected transition zone;
determining an actual occupancy percentage of the occupancy defined zone of the feed conveyor;
determining an actual occupancy percentage of the occupancy definition zone of the receiving conveyor;
selecting a desired occupancy percentage of the receiving conveyor after merging articles from the feed conveyor to the receiving conveyor;
feeding the article from the feed conveyor to a occupancy defined zone of the receive conveyor at a selected speed ratio;
merging the articles in the transition zone between the feed conveyor and the receiving conveyor to increase the density of the articles at a desired occupancy of the receiving conveyor after merging the articles from the feed conveyor; adjusting the conveyor speed ratio proportional to the ratio of the desired density to the current density;
generating a table of sensing ranges using a plurality of photoeyes ;
Each photoeye has two outputs, each of which is individually adjustable to acquire two different ranges;
The plurality of photo eyes are selected from a discharge end of the feed conveyor and a receiving end of the receive conveyor on a first side and an opposite second side of the selected measurement area of the feed conveyor and the receive conveyor. installed at a distance of
pulses are generated at selected intervals along the measurement area of the conveyor surface using a programmable virtual encoder;
A method of managing and controlling the density of articles on a conveyor . counting, identifying, and locating items on the receiving conveyor by digital images or footprints;
9. A method of managing and controlling the density of articles on a conveyor according to claim 8. providing a distance sensing conveyor article management system that regulates input flow to the collector conveyor system by positioning a distance sensing photoeye array assembly at each feed conveyor input of said articles to the collector conveyor;
the speed of each feed conveyor input relative to the speed of the collector conveyor can be controlled to maximize the flow of packages through the system;
9. A method of managing and controlling the density of articles on a conveyor according to claim 8. calculating an average parcel size (area or volume), parcel length, parcel width, and parcel height using a control algorithm;
9. A method of managing and controlling the density of articles on a conveyor according to claim 8. identifying, locating, or tracking the item by a digital image, scanner code, or digital footprint using a control algorithm.
9. A method of managing and controlling the density of articles on a conveyor according to claim 8.

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