Conventionally, manual labor has been used to cover a bale of cotton or other fibrous material with a bag to protect the bale from damage or contamination during transport, and some instances to comply with trade requirements. To bag a bale using prior art methods, one or, more commonly, two or more workers must extend an open end of a bag over a bale chute in preparation for the bale to be inserted through the bale chute and into the bag, preventing the workers from accomplishing other tasks during this time. Conventional bale bagging devices also contain numerous moving parts, on which workers may catch themselves or clothing, causing serious injuries, death, and/or property damage.
The present invention provides a bag retrieval assembly and bag, which facilitate the covering of a bale of cotton or other fibrous material. The bag is configured to be used with the bag retrieval assembly, which is configured to manipulate the bag from a stacked or stored configuration to an open configuration that may be raised and held into a position for further processing. The present invention may reduce manual labor requirements, protect the bale from damage or contamination during transport, and in some instances, help to comply with trade requirements.
In one aspect, a bag is provided which includes a body portion having a bottom end, opposed first and second panels extending from the bottom end, and opposed first and second side panels extending from the bottom end and connecting the first and second panels. The bottom end, the first and second panels and the first and second side panels are assembled together to define a receptacle space. The receptacle space has an open end located opposite the bottom end. The bag also includes a cutout portion defined on the first panel. The cutout portion is positioned at a location on the first panel more proximate to the open end than to the bottom end. The bag may also include a mark positioned proximate to the cutout portion, such that the mark provides an indication of the location of the cutout portion, for example, to a visualization system.
Also provided herein is a bag for bagging a pressed bale comprising a body portion having a bottom end, opposed first and second panels each comprising an exterior surface and an interior surface extending from the bottom end, and opposed first and second side panels extending from the bottom end and connecting the first and second panels; the bottom end, the first and second panels and the first and second side panels defining a receptacle space with an open end located opposite the bottom end. A cutout portion is formed through the exterior surface and the interior surface of the first panel, the cutout portion positioned at a location on the first panel nearer the open end than the bottom end: and wherein when the open end is closed, the cutout is covered on the interior surface side by the interior surface of the second panel.
In another aspect, a bagging system is provided including a bag retrieval assembly for retrieving a bag, a bag positioning assembly for opening the bag retrieved by the bag retrieval assembly and preparing the bag to receive a bale, and a bag stuffing assembly for inserting the bale into the bag. The bag retrieval assembly includes a robotic device configured to move along variable paths to variable positions: and an end effector coupled to the robotic device. The end effector includes a beak assembly, and a visualization system configured to detect and isolate features of a digitized image. The beak assembly and the visualization system are each mounted generally in-line along a central axis of end effector.
In yet another aspect, a method for retrieving a bag for use in a bagging system is provided. The method includes detecting a cutout defined on a first side of a bag; moving a beak assembly having a first arm and a second arm into a position proximate to the cutout; inserting at least a tip of the first and second arms into the cutout; and expanding the beak assembly until the distance between the tips of the first and second arms is greater than the diameter of the cutout.
In still yet another embodiment, a method for retrieving a bag for use in a bagging system is disclosed. The method comprising detecting an indicium defined on an exterior surface of a first side of a bag; moving an end effector towards the indicium; deploying an attachment device mounted on the end effector to grab the bag; and wherein the attachment device comprises a vacuum source.
In yet another embodiment, a method for retrieving a bag and placing a pressed bale into the bag is provided. Said method comprising the steps: moving a pressed bale into a bale bagging assembly; inserting a probe into a cut section of a bag, said bag sized for bagging a pressed bale; opening an open end of the bag; moving the bag and the probe relative to one another to separate the bag from the probe; and moving the pressed bale into the bag through the open end of the bag.
Other aspects and variations of the bag and bag retrieval assembly summarized above are also contemplated and are more fully understood when considered with respect to the following disclosure.
FIG. 2B(a)-(c) are illustrations of exemplary cutout features for use with the bag of
The detailed description set forth below in connection with the appended drawings is intended as a description of the presently preferred embodiments of a bag and a bag retrieval assembly provided in accordance with aspects of the present invention and is not intended to represent the only forms in which the present invention may be constructed or utilized. The description sets forth the features and the steps for constructing and using the bag and bag retrieval of the present invention in connection with the illustrated embodiments. It is to be understood, however, that the same or equivalent functions and structures may be accomplished by different embodiments that are also intended to be encompassed within the spirit and scope of the invention. As denoted elsewhere herein, like element numbers are intended to indicate like or similar elements or features.
To facilitate an understanding of the embodiments of the bag and bag retrieval assembly of the present invention, the general architecture and operation of a preferred bagging assembly is described, which is disclosed in Ser. No. 61/033,376 and previously incorporated herein by reference.
In an exemplary embodiment, bagging assembly 100 includes a system area 102, which houses various bale bagging components generally referred to herein as a housing, having a base 104, that may be a floor or a slab or a metal frame or foundation, side walls 106, that may be metal, plastic, wood or steel frames or steel beams, and a top wall 108, that may be a roof of a building or an upper frame or beam.
Bagging assembly 100 includes, within housing 102, a bag retrieval assembly 110 for retrieving bags from a stack of bags 118, a bag positioning assembly 112 for opening the bag and preparing the bag over a chute to receive a bale, and a bag stuffing assembly 114 for stuffing or inserting the strapped bale into the bag. Generally speaking, bagging assembly 100 operates continuously to retrieve a bag 116 from a stack of bags 118, position bag 116 to receive a bale 120, insert bale 120 into bag 116, seal bag 116, and push the sealed bag off of the assembly to then bag a next bale. The foregoing description is described in detail in provisional application No. 61/033,376.
Bag 116 may be formed by folding and assembling a length of material, using adhesives, heat or pressure welding, sewing or other well known bag assembling techniques. The length of material may include, but is not limited to plastic, burlap, cotton, nylon, polypropylene, polyethylene, polyester, paper, or similar bag making materials. Bag 116 may be adapted so that the body of the bag is convertible between an expanded use configuration (
A hole or cutout 210 is formed on and extends through first panel 202 of bag 116. It should be understood that the position of cutout 210 on first panel 202 is governed, at least in part, by movement and operation of the bag retrieval assembly 110 for “picking-up” bag 116, as described in detail below. Generally, however, cutout 210 may be positioned on first panel 202 in relative proximity to open end 206 of bag 116. In one embodiment, cutout 210 is positioned closer to open end 206 than to bottom end 208. Most preferably, the cutout 210 is located on only one of two panels, such as the first panel 202 and not also the second panel 204. Also, when the bag is in a closed configuration and laid flat, the cutout 210 is superimposed against a solid surface layer of the second panel 204. Although other cutouts may be incorporated elsewhere on bag 116, the main cutout 210 on the first panel should not have a corresponding cutout located on the second panel. This allows a pickup to grab the bag 116 by only one of its side panels, as further discussed below. In a broadest aspect of the present invention, an indicium is provided on an exterior surface of the first panel 202 for use by a detection system to move towards the bag to then enable a retrieving device to grab the bag. The indicium can be a cutout, several cutouts, a mark, a combination mark and cutout, a logo, a hook, a notch, a metal insert, a sensor, a radio frequency identification (RFID) member, combinations thereof and similar devices to enable detection by a detection system. In one example, a support grommet is added to a bag having a cutout to facilitate pickup by allowing additional detection mechanism to key in on the grommet. The grommet can also add strength or texture to a less sturdy bag. As used herein, a cutout or a slit can be used interchangeable. More generically, a “cut section” may include a cutout or a slit or other cut features, such as a stamped section, a ripped section, a punched section, etc.
In one embodiment, an indicator or mark may be placed on bag 116 to help locate or pinpoint the cutout 210 so that it is more “visible,” especially to a camera system, OCR system, machine vision system or similar visualization systems, which uses the cutout and/or the indicator to locate a grabbing mechanism relative to the cutout to pick up the bag. For example, in one embodiment, cutout 210 may be encircled with a contrasting color band or other contrasting feature 212a, such as reflective coating or paint. In other embodiments, cutout 210 may be formed of varying geometrical shapes, features or combinations thereof. For example, with no intent to be limiting but only exemplary. FIGS. 2B(a)-(c) illustrate cutout 210 as a polygon, an ellipse, and a star. In yet another alternative embodiment, a specific mark 212b, such as a word or a logo may be positioned proximate to cutout 210, or may incorporate all or a part of cutout 210 into the mark 212b, to indicate the location of cutout 210. A mark 212c may be placed on first panel 202, such that when mark 212c is detected by the visualization system, the location of cutout 210 may be determined relative thereto. However, other schemes and devices or sensors for detecting edges, visual contrasts, marks, etc. may readily be used without deviating from the spirit and scope of the present embodiment.
Bag 116 is stacked on stack of bags 118, such that first panel 202 and cutout 210 are exposed at the top of stack 118 to be accessed by bag retrieval assembly 110 (
End effector 302 may be manipulated with robotic arm 304 using well-known robotic motion techniques controlled by a computer, vector drives, servo drives, electro mechanical sensors and/or other common control devices known in the art. These controllers may be closely placed, producing a master control center, or each device may have its own controller, wherein signals coordinate functions between systems. Alternatively, a Cartesian coordinate robot may be used to move the end effector to perform the bag pickup function, as further discussed below.
In one embodiment, with reference to
As shown in
A bag attachment mechanism 314 may also be coupled to end effector 302 and used to secure bag 116 to end effector 302. In one exemplary embodiment, bag attachment mechanism 314 may include a vacuum device capable of generating an effective amount of vacuum so that as end effector 302 is raised, bag 116 is held by a vacuum force and rises with the end effector. For example, bag attachment mechanism 314 may include a plurality of vacuum cups 316 used to ensure that bag 116 is secured to end effector 302. Alternatively, a perforated vacuum plate, or any other device suitable to enable end effector 302 to “grab” bag 116 to be removably attached to end effector 302 may also be used as an alternative to, or in addition to, vacuum device 314. In one embodiment, a sensor (not shown) may be incorporated into end effector 302 so that as it contacts bag 116, a signal is sent to a controller to activate vacuum device 314.
Referring now to
Alternatively, visualization system 310 may be used to detect other features of bag 116, other than cutout 210. For example, visualization system 310 may detect a logo or word, a geometric feature, a plurality of geometric features, a tag and the like, located away from cutout 210. Detection of one of these alternative features may cause a signal to be sent to the robotic controllers, which in turn, causes the controllers to manipulate end effector 302 into a desired position relative to cutout 210. Generally, the desired position is where central axis 312 of end effector 302 and visualization system 310 are substantially in direct alignment with the geometric center of cutout 210.
With reference now to
As shown in
As shown in
In one embodiment, driving mechanism 702 may include hydraulic or pneumatic cylinders 704 coupled to cylinder rods 706. In operation, when cylinders 704 are energized, rods 706 are made to retract, or expand depending on the mechanical configuration. As shown in
In one operational embodiment, to aid in securing bag 116 to end effector 302, while beak assembly 306 is inserted into cutout 210, arms 708 and 710 may be expanded a distance a which is greater than the diameter C of cutout 210. As arms 708 and 710 expand to distance D, an outer surface 716 of each arm 708 and 710 is made to contact an inner surface of cutout 210. The continuing expansion of arms 708 and 710 to distance D causes a portion of bag 116 proximate to cutout 210 to migrate up along arms 708 and 710. Because distance D is greater than diameter C of cutout 210, tips 712 and at least a portion of arms 708 and 710 are positioned securely within the interior of bag 116. The expanded tips 712 and arms 708 and 710 secure bag 116 to end effector 302.
As shown in
As end effector 302 ascends to its initial position with bag 116 attached, bag 116 is ready for further processing by bagging assembly 100 (
Referring now to
In one embodiment, the cut section 406 is a slit formed on only the first panel 202 of the bag 116. The cut section 406 may be about 2 to about 12 inches in length and about 1 to 10 inches from an edge of the indicium 212. Other dimensions may be incorporated without deviating from the spirit and scope of the present embodiment. However, it is understood that the cut section may represent other cut shape, such as a circle, an oval, a rectangle, etc. with a slit being more preferred. Thus, once the indica 212 is detected by the visualization system 404, the location of the slit 406 relative to the indica may be computed and the robot 400 be programmed to move to and interact with the slit to pick up the bag, as further discussed below. Like previously described bags, the current bag embodiment has an open end 206 to which the indicium 212 and the slit 406 are aligned. Most preferably, the slit and the indicium are centered relative to the two side edges 212d and 212e of the bag 116 and are positioned closer to the open end 206 than the closed end 208. In one embodiment, the slit is located about 4 to 8 inches from the open edge of the bag.
With reference now to
Referring again to
The two spreader prongs 410a, 410b are generally similar in configuration with one of the prongs incorporating an overhang section for covering the tip of the other prong, as further discussed below. Thus, the discussion hereinbelow regarding the spreader prongs 410a, 410 are with reference to only one of the prongs with the understanding that it applies equally to the other. The spreader prong 410a comprises two or more wing sections, which in the current embodiment includes a proximal wing section 418 and a distal wing section 420. The two sections 418, 420 are joined together along a corner 422, which has a bore or opening 424 for receiving a rotatable pin 426. The proximal wing section 418 further incorporates a second bore or opening 425 for receiving a second pin 428. The first rotatable pin 426 is thus in pivoting communication with the corner opening 424 of the spreader prong and the corresponding opening of the pickup probe 412a while the second rotatable pin 428 is in pivoting communication with the outer opening 425 of the spreader prong 410a and the corresponding opening of the pickup probe 412a. The second rotable pin 428 is also in pivotable with both the upper and the lower mounting brackets 408a, 408b. Hence, when the actuator cylinder 450 is actuated, the piston rod on the cylinder 450 pushes on the inner pin 426, which causes the spreader prong 410a and the pickup probe 412a to pivot about the outer pin 428, as shown in
The distal wing section 420 incorporates a cutout 430, which in one embodiment is a half-circle configuration that can alternatively embody other shapes, such as a half square, a half rectangle, etc. When the pickup head 402 is in a closed or probing position as shown in
Referring again to
Along the distal direction, the distal probe section 436 incorporates an enlarged catch portion 446, which has an apex 448 and optional frictional features such as bumps, fingers, brillo pad type fabric, etc. to facilitate gripping the bag 116 when moving to an open bag grabbing position, as further discussed below. In one particular embodiment, one of the distal probe sections incorporate an overhang 452 having an undercut area 454 to accommodate the enlarged catch section 446 of an adjacent probe. The overhang 452, which functions like a cap, covers a seam 456 that is located between the two probes 412a, 412b. Thus, when the pickup head 402 moves in the direction of the arrow 458 to penetrate and catch the slit 406 on the bag 116, the chance of just one probe entering the slit or catching an object in the seam 456 is minimized. The various components of the preferred pickup head 402 may be made from metal, such as steel or stainless steel, a composite material, or a hard plastic with steel being most preferred.
The pickup process will now be discussed with reference to
The pickup head 402 is then moved to a closed position (
In one embodiment, the pickup head 402 is configured to move a predetermined axial distance once the probe is inserted into the slit. For example, the robot may be programmed to move approximately the same distance as the distance of the distal probe section measured from the tip of the overhang 452 (
The pickup head 402 is now actuated to move to an open position as shown in
When the bag 116 is raised and because it is only held on one side, the open end 206 of the bag opens further due to gravity. A blast of air from an appropriately placed nozzle could, if needed, assist in opening a bag made from a material that may not want to naturally separate, such as due to static elasticity or natural adhesion forces. The open end can now be entered by the positioning arms on the bag positioning assembly 112 (
In still yet another embodiment, an end effector comprising a single probe (not shown) is used to engage a cut section of a bag to separate the bag from a roll of bags or a stack of bags. The single probe may have a barb end, a frictional tip, and/or a hook end so that once the probe enters the cut section, the probe engages the bag and may be lifted without a spreader device. Yet in another embodiment, an end effector comprising a plurality of spaced apart probes, similar to a fork, may be used to pick up a bag.
Although embodiments of the bag and bag retrieval assembly have been specifically described and illustrated, many modifications, combinations, and variations of the embodiments will be apparent to those skilled in the art. For example, the dimensions of the bag and the positioning of the robotic device within the housing may be modified to achieve their intended purpose. Furthermore, although specific features and aspects may be discussed for a particular embodiment, they are understood to be useable and may be incorporated in other embodiments provided to functions are compatible. For example, where the end effector of
This is a divisional application of co-pending application Ser. No. 12/626,558, filed Nov. 25, 2009, which is a regular utility application of provisional application Ser. No. 61/118,175, filed Nov. 26, 2008, which expressly incorporates by reference U.S. provisional Application Ser. No. 61/033,376, filed Mar. 3, 2008. The contents of each of the foregoing applications are expressly incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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61118175 | Nov 2008 | US |
Number | Date | Country | |
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Parent | 12626558 | Nov 2009 | US |
Child | 13660859 | US |