The present invention relates to methods, apparatus and systems for the handling of empty, flat folded storage bags in preparation for filling with a flowable material. Flowable material includes powdery materials such as cement powder, particulate material such as sands, seeds, pelletized material, etc.
The invention is considered particularly suited for though not limited to the handling of flat folded valve bags; that is, bags which have a flat-folded filling valve at one end of the bag.
There are numerous automated systems for the handling of empty, flat folded storage bags in preparation for filling with a flowable material. Many include a magazine assembly having a chamber in which bags to be filled are initially stacked, then sequentially removed or fed from the chamber and transported by various means to a filling station. Some systems involve one-by-one removal of bags from the top of a magazine chamber. Others involve one-by-one removal of bags from the bottom of a magazine chamber.
Examples of systems where stacked bags are automatically removed from the top of a magazine chamber include those disclosed in U.S. Pat. No. 3,466,837 (Sturges) granted on Sep. 16, 1969; U.S. Pat. No. 4,970,847 (Gradwohl) granted on Nov. 20, 1990; U.S. Pat. No. 5,050,651 (Hejlesen) granted on Sep. 24, 1991; and U.S. Pat. No. 7,194,849 (Komp) granted on Mar. 27, 2007.
Examples of systems where stacked bags are automatically removed from the bottom of a chamber include those disclosed in U.S. Pat. No. 2,332,187 (Allen) granted on Oct. 19, 1943; U.S. Pat. No. 3,989,073 (Remmert) granted on Nov. 2, 1976; U.S. Pat. No. 4,345,629 (Inglett) granted on Aug. 24, 1982; U.S. Pat. No. 6,705,606 (Summa) granted on Mar. 16, 2004; and Japanese Publication No. JP 7277307A (Sakai) published on Oct. 24, 1995.
Various problems can arise in the operation of such systems.
One potential problem is adherence between adjacent bags. For example, two bags may be held together by a small spot of leaked glue. The strength of adherence may be weak, but nevertheless sufficient to compromise automated one-by-one removal of bags from a magazine chamber.
Another potential problem involves the flatness of the bags. Merely because the bags are “flat folded” does not mean they are flat or will lie in flat planes atop one another when stacked in a chamber. Their surfaces may have some bowing, rippling or other distortion away from planar flatness. Such distortions can compromise reliable separation and dispensing of individual bags from the chamber.
A further potential problem with many known systems is the lack of a suitable operating strategy in the event there is a malfunction in the mechanisms used to transport bags from a magazine assembly to a bag filling station. Even though the magazine assembly may remain serviceable, a failure in the transport mechanism may dictate a complete system shutdown. This problem can arise, for example, in a system like that of Sturges, supra, where bags are gripped and removed from the top of a magazine chamber and, with the same mechanism, are then transported directly to a bag filling station. As another example, it can also arise with a system like that of Sakai, supra, where bags are gripped and removed from the bottom of a magazine chamber and, with the same mechanism, are then transported directly to a bag filling station.
In the case of flat folded valve bags, other problems can arise—for example, the reliable opening of valves to enable filling at a bag filling station. Typically, the mechanism which is used to transport a valve bag to a bag filling station will include a means to open the valve at the time it grips the bag. The transport mechanism then steers the bag with its opened valve over a filling nozzle at the bag filling station. However, if the nozzle encounters a bag with a valve which is incompletely opened, and if the problem cannot be corrected, then the bag has to rejected. In an automated system, it is obviously desirable to minimize the frequency of such occurrences. This requires consideration not only of the mechanism used to open valves but also the manner in which bags are presented to the bag filling station.
As another example in the case of flat folded valve bags, the manner in which the bags are stacked in a magazine chamber can become an issue. The thickness of each flat folded bag typically may not be uniform along the length of the bag. When stacked on top of one another in a magazine chamber, the result can be a stack where the upper bags in the stack progressively become more and more tilted within the chamber as the number of bags is increased—eventually to an unworkable degree which limits the addition of more bags to the stack.
Various aspects of the present invention address the foregoing issues. Generally, there is a need for new and improved methods and apparatus for handling empty, flat folded storage bags, including flat folded valve bags, in preparation for filling with a flowable material. The need exists not only from an overall system point of view beginning with the structure and operation of a bag holding magazine assembly and ending with the presentation of empty bags to a bag filling station, but also in relation to intermediate stages of handling.
In one aspect of the method of the present invention there is provided a method of handling empty, flat folded storage bags in preparation for filling with a flowable material, the method comprising seating and stacking a plurality of the bags on a fixed elevation base within a chamber of a bag holding magazine assembly, the resulting stack defining an initial stack rising from a lowermost one the bags on the base to an uppermost one of the bags. Then, in a first cycle of operation, all but the lowermost bag is raised away from the base, the raised bags defining a depleted stack of bags. Then, while the depleted stack remains raised, the lowermost bag is removed from the chamber through a chamber outlet opening. Then, the depleted stack is lowered to seat a new lowermost bag on the base. This completes the first cycle of operation. The first cycle is then repeated for each lowermost bag.
It may be noted that the system of Sakai, supra, contemplates a magazine chamber where the base on which bags are stacked does not have a fixed elevation. Rather, the base is repeatedly lowered and raised as stacked bags are sequentially removed from the chamber. When the base is lowered, it is lowered carrying with it the lowermost bag in the stack to align with a pair of clamping jaws designed to grip on an end of the lowermost bag. During the step of lowering, each lowermost bag needs to be held to the base by bag gripping means which move up and down with the base. The jaws are then operated to pull the lowermost bag from the chamber and to carry the bag to a bag filling station. All remaining bags remain stacked in their original position within the chamber. When the base is subsequently raised, the remaining stack becomes seated on the base. The repeated raising and lowering of the base, including the requirement to maintain a grip on the lowermost bag, is dictated by the necessity to repeatedly align lowermost bags with the clamping jaws. The present invention does not involve such criteria.
In a further aspect of the method of the present invention, each lowermost bag removed from the magazine chamber is removed by feeding the bag to an outlet opening in the chamber, then conveying the bag through the opening to a bag pick-up position located away from the magazine assembly. Generally, the prior art (including Sakai, supra) does not appear to contemplate an intermediate pick-up position. It appears to contemplate grabbing a bag from a magazine chamber and transporting it directly to a bag filling station. Such systems are considered to be undesirable. If the transport mechanism fails, then the result may be a complete system shutdown. On the other hand, with an intermediate pick-up station, if a system for automated pick-up fails, then a system for manual pick-up can be substituted during the time when maintenance procedures may be required. In short, operations may carry on despite partial failure of the system.
In another aspect of the method of the present invention, each lowermost bag is removed from the magazine chamber by conveyance through an outlet opening in the chamber to a pick-up position located on a bag transfer station. The method further comprises automatically lifting the bag away from the pick-up position and carrying the lifted bag to a bag filling station for filling flowable material.
The bags mentioned above may be valve bags which have an openable flat-folded filling valve at one of their ends.
In yet another aspect of the method of the present invention, the method further comprises opening the filling valve of each bag at its pick-up position before carrying the bag to a filling station. Opening may be achieved by applying suction to a top surface of the valve while momentarily holding the bag in its pick-up position. Preferably, the suction holds the valved end of the bag in a valve shaping channel member of a bag carrying tool with the filling valve fully opened, the channel member comprising an elongated top and opposed sides extending downwardly and outwardly from the top to an open bottom; and wherein the suction is maintained while carrying the lifted bag to the bag filling station.
In yet a further aspect of the method of the present invention the magazine chamber described above extends front to back between a chamber forward end and a chamber rearward end, and transversely between opposed chamber sides. Each lowermost bag removed from the chamber is removed through an outlet opening in the rearward end. Preferably, the distance between sides of the chamber is adjustable.
In a still further aspect of the method of the present invention it has been found that bags when stacked in a magazine chamber can, to advantage, be stacked in groups of bags with longitudinal staggering between the groups. Particularly in the case of valve bags or other bags which have unequal flat folded thicknesses along their length, staggering can reduce the amount of progressive tilt mentioned above thereby enabling more bags to be stacked without encountering excessive tilt.
In a further aspect of the present invention, there is provided a magazine assembly for handling and sequentially supplying bags from a stack of empty, flat folded storage bags in preparation for filling with a flowable material, each bag having opposed ends and opposed sides extending between the ends, and each bag having opposed top and bottom surfaces between the ends. The stack extends upwardly from a lowermost one of the bags to an uppermost one of the bags. The magazine assembly comprises a chamber for holding the stack, a fixed elevation base, an elevator mechanism and a bag removal mechanism.
The magazine chamber extends front to back between a forward end of the chamber and a rearward end of the chamber, and transversely between opposed sides of the chamber. The rearward end provides an outlet opening permitting removal of bags in the stack from the chamber through the opening. Preferably, the chamber sides are distanced from each other by an adjustable amount.
The base has an upper surface for providing a seating for the stack within the chamber with the lowermost bag resting on the base. The upper surface is aligned with the outlet opening.
The elevator mechanism is for selectively raising within the chamber all but the lowermost bag while holding the lowermost bag on the base, the raised bags defining a depleted stack of bags, and for lowering and seating the depleted stack on the base when the lowermost bag has been removed from the chamber.
The bag removal mechanism is for removing the lowermost bag from the chamber through the outlet opening while the depleted stack remains raised.
Preferably, the elevator mechanism comprises a pair of elevator guides, one positioned outside one side of the chamber, the other positioned outside the opposite side of the chamber, a pair of elevator trucks, and gripper mechanisms for gripping and downwardly bending the opposed sides of the lowermost bag when the bag is rested on the base. The trucks each have a forward end comprising a plurality of lifting forks positioned between opposed sides of the truck. The trucks are carried and guided by respective ones of the guides for reciprocal movement in unison between lower positions where the forks are distanced away from the chamber and upper positions where the forks project into the chamber.
The elevator mechanism is disposed such that as the trucks move upwardly from lower positions to upper positions when the opposed sides of the lowermost bag are bent downwardly, then the forks bypass the lowermost bag and engage the stack below the bag next above the lowermost bag, such engagement occurring before the trucks reach maximally upward positions.
Advantageously, the forks on each truck project inwardly relative to the chamber at a downward angle (e.g. about 6 degrees). To further advantage, the forks on each truck have lengths which vary from relatively short lengths for those ones of the forks positioned towards opposed sides of the truck to longer lengths for those ones of the forks positioned midway between truck sides.
The gripper mechanisms may comprise a first plurality of pivotally mounted suction cups for releasably applying suction grips at a first plurality of locations on the bottom surface of one side of the lowermost bag, and a second plurality of pivotally mounted suction cups for concurrently releasably applying suction grips at a second plurality of locations on the bottom surface of the opposed side of the lowermost bag. As an enhancement to the gripper mechanisms, there may be provided plungers for momentarily urging the bottom surface of the lowermost bag against the suction cups when suction is applied. This better ensures that when suction is applied it will be effective.
The fixed elevation base may comprise a pair of longitudinally extending rails, each rail having an upper surface forming part of the upper surface of the base. The bag removal mechanism may comprise a feed mechanism for feeding the lowermost bag along the rails to the outlet opening of the chamber and means for conveying the lowermost bag through the outlet opening. Advantageously, the means for conveying the lowermost bag through the outlet opening includes upper and lower cooperating rollers for rotationally grasping and drawing the bag through the opening. To further advantage, the upper rollers are preferably crowned pinch rollers.
In a further aspect of the present invention, there is provided apparatus which comprises, in combination with the magazine assembly described above, a bag transfer station for receiving each lowermost bag removed through the outlet opening of the magazine assembly and for conveying the received bag to a pick-up position on the station. From this position, bags may be automatically picked up by suitable means and transported to a bag filling station for filling with flowable material. However, in the event of some failure in the automatic means, the bags may be manually picked up and transported to the bag filling station. The automatic means preferably comprises a robotic arm with a bag carrying tool mounted at a distal end of the arm.
In the case of valve bags, the transfer station and carrying tool are preferably adapted to cooperatively open the valve when the bag is picked up from the transfer station using the robotic arm. Advantageously, the carrying tool comprises a valve shaping channel member into which the valved end of each of the bags is drawn and held when picked up from the transfer station, the channel member comprising an elongated top and opposed sides extending downwardly and outwardly from the top to an open bottom.
The foregoing and other features and advantages of the present invention will now be described with reference to the drawings.
Overall, the bag handling apparatus shown in the figures is adapted to handle flat folded valve bags. However, as indicated below, parts of the apparatus may be used for the handling of flat folded bags which are not valve bags.
To provide a point of reference,
Referring now to
Magazine assembly 20 comprises a magazine chamber 200 which extends longitudinally between a forward end 201 and a rearward end 202, and transversely between opposed sides 203, 204. Opposed flanges 206, 207 extend backwardly from side 203.
Flange 206 provides support for a containment gate 208 (208′, 208″) which is hingedly mounted to the flange and is manually swingable between open and closed positions. In
Magazine assembly 20 also includes a base formed by spaced apart rails 215, 217 which extend between forward end 201 and rearward end 202 of chamber 200. The rails have flat upper surfaces 216, 218 which together provide a seating for bags stacked in the chamber. The elevation of surfaces 216, 218 with respect to chamber 200 is fixed. On the left side of
It will be understood that the bags stacked in chamber 200 need not be valve bags. Bags other than valve bags can be stacked in chamber 200 and the lowermost bag removed from the chamber in the manner described below.
Also, while preferable, it will be understood that the use of rails with flat upper surfaces is not considered to be essential. For example, rails 215, 217 could be replaced by cylindrical pipes or rods. Nevertheless, rails with flat upper surfaces are preferred because they will provide a broader area of underlying support for a stack of bags seated on the rails. Such support is considered to enable a more reliable separation of a lowermost bag from bags stacked above a lowermost bag.
Elevator Mechanism
Magazine assembly 20 further includes an elevator mechanism to selectively raise within chamber 200 all but the lowermost bag in a stack of bags while holding the lowermost bag on the base provided by rails 215, 217. The elevator mechanism comprises an opposed pair of elevator guides generally designated 220, 221. Guide 220 is welded between downwardly sloping opposed support walls 230, 231 which extend perpendicularly away from side 203 of the chamber. Wall 230 is integrally formed with flange 206. Wall 231 is integrally formed with flange 207. Guide 221 is welded between downwardly sloping opposed support walls 232, 233 which extend perpendicularly away from side 204 of the chamber. Each guide carries an elevator truck generally designated 250. The elevator mechanism also comprises bag gripper mechanisms generally designated 270 which are best seen in
The structure of guide 221 is substantially the same as guide 220 and they have a mirror image relationship with each other. However, it will be noted that guide 220 and its elevator truck 250, together with side 203 of magazine assembly 20 and other elements associated with side 203, including rail 215, are slidably carried on an underlying framework generally designated 298 (see
In more detail, each elevator guide 220, 221 comprises a lower end 222 and an opposed pair of rectangular channel members 223, 224, the latter of which extend in parallel at an angle upwardly and inwardly from lower end 222 towards chamber 200. As best seen in
Forks 254-256, are of differing lengths; the lengths varying from relatively short lengths for those ones of the forks positioned towards sides 251, 252 (i.e. forks 254) to longer lengths for those ones of the forks positioned midway between the sides (i.e. forks 256). Such varying lengths are not considered to be essential. However, they have been found to contribute to a more reliable separation of a lowermost bag from a stack of bags within chamber 200 when the bags are not contained in an ideally flat condition.
Also, it will be noted that forks 254-256 project downwardly at a relatively small angle β (beta). In the present embodiment, the angle is about 6 degrees. The provision of this feature (as opposed to having no downward angle) is likewise not considered to be essential. However, it too has been found to contribute to a more reliable separation of a lowermost bag from a stack of bags within chamber 200 when the bags are not contained in an ideally flat condition.
In operation, trucks 250 are reciprocally moved upwardly and downwardly along their associated guides in unison between lower positions (see e.g.
It should be noted that the stacked bags as illustrated in
The movement in unison of elevator trucks 250 is controlled by the concurrent operation of pneumatic cylinders 258 shown in
Referring now to bag gripper mechanisms 270 of which there are two, one of such devices is mounted to rail 215. The other is mounted to rail 217. Generally, their function is to grip and downwardly bend opposed sides the lowermost bag in the magazine chamber when the bag is on the base provided by rails 215, 217.
In more detail,
In the present embodiment, the gripping mechanism has been enhanced with the inclusion of plungers 277, each having a plunger rod 278 with a distal end 279. These plungers are basically pneumatic cylinders, however they are referred to herein as plungers because their cylinder/plunger rods are simply extended and retracted without connection to any other element of the magazine assembly. The present embodiment includes eight such plungers; four of which are mounted outside side 203, the other four of which are mounted outside wall 204 in a mirror image relationship. Only some have been labelled in the drawings.
Normally, plunger rods 278 are retracted to positions outside magazine chamber 200. When extended as shown by way of illustration in
The purpose of plungers 277 is to engage a stack of bags contained within magazine chamber 200 and to momentarily urge the bottom surface of the lowermost bag against suction cups 271 when the suction cups are in a raised position. However, as indicated below and in the drawings, this does require that the plungers act directly on the lowermost bag. The inclusion of plungers 277 has been found to better ensure that a sound suction grip will be achieved when suction is applied by cups 271 and to contribute to a more reliable separation of the lowermost bag from the stack—and again recognizes that bags stacked in chamber 200 may not be contained in an ideally flat condition.
The stages of operation of the elevator mechanism as represented by the positions shown in
Stage 1 (
Stage 2 (
Stage 3 (
Stage 4 (
Stage 5 (
Following Stage 5, cylinder rods 259 of cylinders 258 are then fully extended. This action returns elevator trucks 250 to their lowermost positions. In so doing, depleted stack B2 . . . BN lowers to seat on rails 215, 217. A new cycle of operation may begin and may continue until the original stack is completely depleted.
Bag Removal Mechanism
The mechanism for removing bags from chamber 200 comprises a feed mechanism generally designated 280 for feeding a lowermost bag such as bag B1 when in the position shown in
More particularly, rails 215, 217 extend longitudinally from within chamber 200 beneath rearward end 202, and for a short distance thereafter to upper and lower cooperating rollers for rotationally grasping and drawing a bag through the outlet opening (see
As best seen in
The rollers are not run continuously. In this regard, the bag removal mechanism includes a proximity sensor P6 (see
Feed mechanism 280 comprises a suction cup 290 which is linearly moveable left to right from the position shown in
The operation of the bag removal mechanism as follows. At Stage 1 (
Bags removed from magazine assembly 20 may be handled in various ways, the ultimate objective being to transport them in sequence to a bag filling station. In principle, the job could be done by a worker manually grasping each bag as it leaves the chamber and carrying it by hand to the bag filling station. The same may be done by various automated means.
However, in a preferred embodiment, a bag transfer station 30 as shown in
Note that guide 306 is linked to side 203 of magazine assembly 20. If the distance between sides 203 and 204 of assembly 20 is adjusted to accommodate differently sized bags, then the distance between guides 305 and 306 of transfer station 30 will be correspondingly adjusted.
To better ensure that a bag conveyed by conveyor belt 301 is reliably conveyed to the desired pick-up position, transfer station 30 includes a longitudinally restraining member or band 310 and a transversely extending restraining member or band 311. Here, the problem which is being addressed is that some bags, unless restrained, may undesirably lift and carry over side-wall guide 305 or 306, or may undesirably bounce back from end stop 307.
The distal end of station 30 includes a grated structure 330. This structure is not considered essential, but it is desirable. The purpose is to allow passage of particulate material which may otherwise accumulate at the distal end.
Transfer station 30 includes a proximity sensor P7 for detecting when a bag is in the pick-up position. When presence is detected, the operation of motor 287 is stopped on command from motor controller 287 thereby stopping the operation of conveyor belt 301 and rollers 281, 284, 285. Station 30 also includes a suction cup 320 for momentarily holding the bag at the pick-up position when it is picked up in the manner now to be described.
Referring now to
The function of the proximity sensors is as follows:
Sensor P1: to detect when cylinder rod 259 as shown on the left hand side in
Sensor P2: to detect when cylinder rod 259 as shown on the left hand side in
Sensor P3: to detect when cylinder rod 259 as shown on the right hand side in
Sensor P4: to detect when cylinder rod 259 as shown on the right hand side in
Sensor P5: to detect when pivot arm 291 as shown in a
Sensor P6: for detecting when a bag has been fed to a point where it may be grasped by rollers 281, 284, 285 as described above.
Sensor P7: described above.
The physical positions of sensors P1 to P5 are not illustrated in the drawings. However, suitable placement will be readily apparent to those skilled in the art.
The solenoid valve bank receives compressed air from supply 240 as an input and, under the control of the PLC, appropriately routes the air as required to pneumatic cylinders 258, 274, 292, 294 and plungers/cylinders 277. In
Referring now to
Arm 40 is programmable and has several degrees of freedom. At the distal end, carrying tool 50 can be lifted and lowered, rotated on a vertical axis (e.g. compare
In
In more detail, carrying tool 50 comprises several elements including an upper supporting framework 51 and a lower base structure 52, the latter of which carries a valve shaping channel member 70 defined by an elongated top and opposed sides extending downwardly and outwardly from the top to an open bottom. Base structure 52 is spring-mounted to framework 51 by means of compression springs 53. Further, tool 50 includes three suction cups 55, 56, 57. Pneumatic connections to the suction cups are not shown.
When a bag such as bag B1 is being carried by tool 50, then as best seen in
When preparing to pick up a bag such as bag B1 from transfer station 30, robot arm 40 first performs an alignment operation. Channel member 70 is oriented to extend lengthwise over the flat-folded valved end of the bag. Suction cups 55, 56, 57 are all positioned over the valved end, suction cup 55 being in axial alignment with suction cup 320. When robot arm 40 then directs tool 50 from the upper position shown in
Although the present invention has been shown and described in considerable detail, it should be understood by those skilled in the art that we do not intend to limit the invention to the embodiments described since various modifications, omissions and additions may be made to the disclosed embodiments without materially departing from the novel teachings and advantages of the invention. The intention is to cover all such modifications, omissions, additions and equivalents as may be included within the spirit and scope of the invention as defined by the following claims. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures.
Number | Name | Date | Kind |
---|---|---|---|
2332187 | Allen | Oct 1943 | A |
3050918 | Helm et al. | Aug 1962 | A |
3462917 | Shigeo | Aug 1969 | A |
3466837 | Sturges | Sep 1969 | A |
3691715 | Kelly et al. | Sep 1972 | A |
3715858 | Durant et al. | Feb 1973 | A |
3989073 | Remmert | Nov 1976 | A |
4122649 | Sawvel | Oct 1978 | A |
4141392 | Moltrasio | Feb 1979 | A |
4334558 | Durant | Jun 1982 | A |
4345629 | Inglett | Aug 1982 | A |
4442874 | Ballard, Jr. | Apr 1984 | A |
4577454 | Wright et al. | Mar 1986 | A |
4970847 | Gradwohl | Nov 1990 | A |
5050651 | Hejlesen | Sep 1991 | A |
5346200 | Sarvik et al. | Sep 1994 | A |
6705606 | Summa | Mar 2004 | B2 |
6976350 | Greening et al. | Dec 2005 | B2 |
7194849 | Komp | Mar 2007 | B2 |
7363753 | Gates | Apr 2008 | B2 |
7527079 | Wadium et al. | May 2009 | B2 |
20080256905 | Graf | Oct 2008 | A1 |
Number | Date | Country |
---|---|---|
0371955 | Jun 1990 | EP |
7215314 | Aug 1995 | JP |
7277307 | Oct 1995 | JP |
Number | Date | Country | |
---|---|---|---|
20120192527 A1 | Aug 2012 | US |