Bulk bag support for filling

A bulk bag support for filling wherein the bulk bag has plural handles spaced around a top perimeter thereof. The support includes a frame and an elevatable mounting platform mounted on the frame. A plurality of spaced, openable and closeable support hooks are provided on the mounting platform and are selectively activatable for movement between opened and closed positions for selectively gripping and releasing the aforesaid handles. The support hooks, when in the closed position, releasably grip the handles thereby causing the bulk bag to be suspended from the support hooks and, when lifted, above a base member of the frame and to facilitate is filling of the bulk bag. When the support hooks are in the opened position, the handles on the bulk bag are thereby released causing the bulk bag to rest on the aforesaid base member. A yieldable biassing spring is provided for continually urging the support hooks toward the closed position.

FIELD OF THE INVENTION 
This invention relates to a bulk bag support for filling and, more 
particularly, to a support mechanism for facilitating a loading of a bag 
thereon and removal of a bag therefrom. 
BACKGROUND OF THE INVENTION 
Large cardboard boxes, hereinafter referred to as "gaylords" have 
heretofore been used for supplying plastic pellets to consumers thereof, 
particularly, businesses that use plastic for forming various component 
parts made out of plastic. After a gaylord has become empty, it has 
usually been the procedure to reuse the cardboard boxes by collapsing them 
and shipping them back to the supplier of the plastic pellets. Recently 
there has been a move toward converting a supply of plastic pellets in 
gaylords to a supply in bulk bags. The bulk bags are generally easily 
collapsible for reuse. Further, the bulk bags can be lined with a liner so 
that the liner can be interposed between the product carried in the bulk 
bag and the bulk bag itself so as to prevent cross-contamination when new 
product is placed into a bulk bag that is in the process of being reused. 
Loading of empty bulk bags onto an apparatus for facilitating a filling of 
the bulk bag has heretofore been somewhat complicated and has necessitated 
the bulk bag filling operators to position themselves in close proximity 
to filling apparatus thereby making the occupation of the operator 
somewhat dangerous. Bulk bag supports which will eliminate the need for an 
operator to place himself in a dangerous working position is desired. 
Accordingly, it is an object of this invention to provide a bulk bag 
support wherein the bulk bag may be attached to the support from 
essentially a single location in front of the support out of harms way. 
It is a further object of the invention to provide a bulk bag support, as 
aforesaid, wherein the support is movable to locations readily accessible 
by the bulk bag filling operator to thereby enhance the ability of the 
operator to manipulate the bulk bag from a single location in front of the 
support. 
It is a further object of the invention to provide hook members on the bulk 
bag support that are readily manipulatable manually to facilitate loading 
and removal of bulk bags to and from the support. 
It is a further object of the invention to provide a bulk bag support, as 
aforesaid, which is durable, relatively maintenance free and easy to 
operate. 
SUMMARY OF THE INVENTION 
The objects and purposes of this invention are met by providing a bulk bag 
support for filling wherein the bulk bag has plural handles spaced around 
a top perimeter thereof. The support includes a frame and a mounting 
platform mounted on the frame. A plurality of spaced, openable and 
closeable support means are provided on the mounting platform and are 
selectively activatable for movement between opened and closed positions 
for selectively gripping and releasing the aforesaid handles. The support, 
when in the closed position, releasably grips the handles thereby causing 
the bulk bag to be suspended from the support and above a base member of 
the frame and to facilitate filling of the bulk bag. When the support is 
in the opened position, the handles on the bulk bag are thereby released 
causing the bulk bag to rest on the aforesaid base member. A yieldable 
biassing means is provided for continually urging the support toward the 
closed position.

DETAILED DESCRIPTION 
Certain terminology will be used in the following description for 
convenience in reference only and will not be limiting. The words "up", 
"down", "right" and "left" will designate directions in the drawings to 
which reference is made. The words "in" and "out" will refer to directions 
toward and away from, respectively, the geometric center of the device and 
designated parts thereof. Such terminology will include derivatives and 
words of similar import. 
A bulk bag support 10 is illustrated in FIG. 1 along side of an optional 
pallet supply mechanism 11 adapted to supply individual pallets 12 one at 
a time to the bulk bag support 10. A motor driven pallet selecting and 
dispensing mechanism 13 is utilized for effecting the one at a time 
delivery of a pallet 12 to the bulk bag support. The pallet supply 
mechanism 11 is a commercially available mechanism and, per se, does not 
form a part of the invention disclosed in this application. Thus, further 
detailed discussion concerning the pallet supply mechanism 11 will not be 
presented herein. 
The bulk bag support 10 includes a frame 16 having a generally horizontally 
extending base structure 17 and a vertically upstanding column structure 
18 juxtaposed the base structure. In this particular embodiment, the base 
structure 17 includes, as does a base structure 19 on the pallet supply 
mechanism 11, a plurality of parallel and horizontally arranged rotatable 
rollers. The respective rollers are driven by motors 21 and 22 through 
respective transmissions 23 and 24 provided on the base structures 17 and 
18. The rollers are identified by the reference numeral 26 in FIG. 3, the 
axles 27 of which are illustrated in FIG. 1. In order to facilitate 
simultaneous rotation of the rollers or selected groups of rollers, the 
respective transmissions 23 and 24 can be interconnected with the 
individual rollers through conventional sprocket mechanisms 28 illustrated 
in FIG. 3. Conveyor mechanisms utilizing controlled sets of rollers for 
the purpose of conveying objects along a path are conventional and, 
accordingly, further discussion concerning the conveyor mechanism 
represented by the motors 21, 22, the transmissions 23, 24 and the rollers 
26 will not be further detailed. 
The base structure 17 also includes a set of floor mounted support bars 28 
extending in a direction generally parallel to the longitudinal axes of 
the rollers 26. The support structure for the rollers 26 and the drive 
motor 21 and transmission therefor 23 are mounted on brackets 29 which in 
turn are support on the aforesaid support bars 28. 
The aforesaid upstanding column structure 18 include, in this particular 
embodiment, a pair of spaced apart beams 31 and 32 individually supported 
in an upright position on the support bars 28. In this particular 
embodiment, each of the upstanding beams 31 and 32 is secured by 
appropriate gussets 33 to the support bars 28 along side of the 
longitudinal path defined by the plurality of parallel rollers 26. If 
desired, support braces 34 extending between the upstanding beams 31 and 
32 can be provided in order to stabilize the upstanding column structure 
18. A plurality of vertical guides 36 are provided on the upstanding 
column structure 18. In addition, a brace 34 oriented mid-height of the 
upstanding column structure 18 supports a drive motor 37 and a 
transmission 38 therefor. The transmission 38 includes a mechanism for 
converting the output of the drive motor 37 into a movement parallel to 
the vertical longitudinal axis of the upstanding column structure 18. 
A mounting platform 41 is mounted on the upstanding column structure 18 and 
is supported for vertical movement with respect thereto. More 
specifically, the mounting platform includes a pair of vertically upright 
slides 42 that slidingly engage the vertical guides 36 to facilitate a 
guiding of the mounting platform vertically with respect to the upstanding 
column structure 18. A lift mechanism 43 is operatively driven by the 
transmission 38 and drive motor 37 to effect a driven movement of the 
mounting platform 41 in the aforesaid vertical direction. The lift 
mechanism 43 can include a rotating screw driven by the transmission 38 
through a nut fixed to the mounting platform 41 or any other conventional 
drive mechanism for effecting an elevating and a lowering of the mounting 
platform 41 relative to the base structure 17. 
The mounting platform 41 includes a pair of support arms 44 and 46 
extending from the slides 42 to a position overlying the base structure 17 
as illustrated in FIG. 3. Horizontally and laterally extending bracing 47 
and 48 is connected to and extends between the support arms 44 and 46 to 
provide the requisite stabilization for the mounting platform 41. In this 
particular embodiment, extensions 49 and 51 are provided on a respective 
side of the support arms 44 and 46 which are remote from one another so as 
to provide a requisite location for a respective mounting bracket 52 and 
53. Each mounting bracket 52 and 53 includes a plurality of slots 54 that 
extend vertically, are closed at the bottom and opened at the top and face 
outwardly in a first direction parallel to the longitudinal extent of the 
support arms 44 and 46. Further extensions 56 and 57 are provided on the 
support arms 44 and 46, but at an end of each thereof that is remote from 
the brace 47 and extensions 49 and 51. Mounting brackets 58 and 59, 
similar to the mounting brackets 52 and 53, are mounted on the extensions 
56 and 57. Each of the mounting brackets 58 and 59 have a plurality of 
vertically extending slots 61 identical in kind to the slots 54, namely, 
they are closed at the bottom, opened at the top and face the slots 54. 
The slots 61 are, furthermore, aligned in a direction parallel to the 
longitudinal axis of the support arms 44 and 46 and with the slots 54. 
An elongated support arm bracket 62 is mounted on each pair of opposing 
mounting brackets, 52, 58, and 53, 59. Each support arm bracket 62 
includes an elongated bar 63 terminating at opposite ends in a pair of 
pins or a flat bar flange 64 receivable into the respective slots 54, 61 
in each of the mounting brackets 52, 53, 58 and 59. As a result, the 
elongated bars 63 become oriented, when mounted on the mounting brackets 
52, 53, 58 and 59 in an arrangement wherein the longitudinal axis thereof 
is parallel to the longitudinal axes of the support arms 44 and 46 and 
they overlie the rollers 26 on the base structure 17. 
FIG. 4 illustrates an enlargement of a first embodiment of the support arm 
brackets 62. This bracket is being viewed in the direction IV illustrated 
in FIG. 2. A first end 66 of the elongated bar 63 has a hook supporting 
bracket 67 fixedly secured thereto by a plurality of fasteners 68, such as 
bolts. A plurality of holes 69 in the elongated bar 63 are oriented in an 
array that extends parallel to the longitudinal axis of the elongated bar 
63 to facilitate an orientation of the hook support bracket 67 at 
differing locations along the length of the elongated bar 63. As shown in 
FIG. 8, the bracket 67 includes a support extension 71 and a connector 72A 
for supporting one end of a pneumatically operated cylinder 72. The 
aforesaid connector 72A for connecting the pneumatic cylinder 72 to the 
support extension 71 renders that end of the cylinder pivotal with respect 
to the support extension. 
The hook supporting bracket 67 also includes a hook mechanism 73 pivotally 
secured to the bracket 67 by means of an axle arrangement 74. The hook 
mechanism 73 includes a hook member 76 having an arcuately shaped, 
upwardly facing bulk bag handle engaging surface 77 having a distal end 
abutting a part 79 of the supporting bracket 67. The center of the arcuate 
handle engaging surface 77 coincides with a pivot axis defined by the axle 
arrangement 74 for the hook member 76. As a result, and when a weight 
force from a handle on the bulk bag is applied to the handles looped over 
the aforesaid handle engaging surface 77, the force will be transmitted 
through the axle 74 to the hook supporting bracket 67 and thence the 
support arm bracket 62. 
A manually engageable lever 81 is connected to the hook member 76 and is 
pivotal therewith about the axle 74. A torsion spring 82 encircles the 
axle 74 with one leg 83 thereof being connected to the hook supporting 
bracket 67 and the other leg 84 thereof abutting against a pin 85 that is 
mounted on and movable with the hook member 76. The torsion spring 82 
biases the hook member 76 to the closed position wherein the distal end 78 
of the handle engaging surface 77 abuts the part 79 of the bracket 67 so 
that any bag handle supported on the surface 77 cannot be inadvertently 
released from the hook member 76. 
The hook member 76 further includes an arm 86 that projects from the axle 
74 on a side thereof remote from the lever 81 and is connected as at 87 
via a pivot connection to the reciprocal rod part 88 of the pneumatic 
cylinder 72. Extension of the rod 88 from the pneumatic cylinder 72 in 
response to a pneumatic activation thereof will drive the hook member 76 
from the closed position illustrated in FIG. 8 counterclockwise about the 
axle 74 to an opened position wherein the distal end 78 is positioned away 
from the part 79 of the bracket 67. Deactivating of the pneumatic cylinder 
72 by the removal of air therefrom will cause the torsion spring 82 to 
drive the hook member 76 from the opened position to the closed position 
illustrated in FIG. 8. 
The elongated bar 63 at a second end 89 thereof includes a hook supporting 
bracket 91 that is slidably mounted on the elongated bar 63. To facilitate 
the sliding mounting, the bracket 91 includes a hollow support 92 (FIG. 9) 
that encircles the elongated bar 63 with the interior surfaces 93 thereof 
each engaging a low friction liner material 94, such as NYLON, TEFLON or 
the like secured to the exterior surface of the elongated bar 63 by a 
plurality of fasteners 95. A pneumatic cylinder 96 is secured to the 
elongated bar 63 by a bracket 97 and plural fasteners 98. The distal end 
99 of the rod 101 of the cylinder 96 is secured to the hollow sleeve 92 of 
the hook supporting bracket 91 by a fastener 102. Extension and retraction 
of the rod 101 out of and into the pneumatic cylinder 96 will effect a 
sliding movement of the hollow sleeve 92 and thence the hook supporting 
bracket 91 lengthwise of the elongated bar 63. 
The hook supporting bracket 91 includes a hook mechanism 73 identical to 
the hook mechanism provided on the hook supporting bracket 67. Thus, 
further comment about the construction of the hook mechanism is believed 
unnecessary. 
It will be noted from a review of FIG. 4 that the distal ends 78 on the 
respective hook mechanisms 73 face away from each other. Thus, an operator 
standing near or adjacent the first end 66 of the elongated bar 63 will be 
able to reach the hook mechanism 73 on the bracket 91 when the rod 101 is 
retracted into the pneumatic cylinder 63 and, when the pneumatic cylinder 
72 is activated to open the hook in a counterclockwise direction in FIG. 4 
and expose the arcuately shaped, upwardly facing handle engaging surface 
77, place a loop of the handle onto or over the open and exposed surface 
77. Thereafter, the air supply to the pneumatic cylinder on the bracket 91 
can be exhausted so that the torsion spring 82 will effect a closing of 
the hook member 76 to trap the handle on the hook member 76. Similarly, 
activation of the pneumatic cylinder 72 on the hook supporting bracket 67 
at the first end 66 will cause the hook member 76 to pivot clockwise and 
open the arcuately shaped, upwardly facing handle engaging surface 77 to 
facilitate insertion of a handle thereon. If desired, manual manipulation 
of the respective handles 81 is permitted at all times when air pressure 
is not supplied to the pneumatic cylinders 72 so that the handles on the 
bulk bag can be removed or inserted without necessarily activating the 
pneumatic cylinders 72. In other words, and with the air supply off, the 
piston within each of the pneumatic cylinders 72 is free floating and it 
is only the respective torsion springs 82 that are maintaining the hook 
members 76 in the respective closed positions illustrated in FIG. 4. 
The embodiments illustrated in FIGS. 5 and 6 are closely similar to the 
embodiment illustrated in FIG. 4. In FIG. 5, two hook supporting brackets 
67 are mounted at the respective first and second ends 66 and 89 of the 
elongated bar 63 and are fastened thereto by plural fasteners, here bolts 
68. In order to accommodate this construction, holes 69 are provided in 
the elongated support bar adjacent each of the first and second ends 66 
and 89. FIG. 6, on the other hand, is similar in many respects to FIG. 5 
except that there are no pneumatic cylinders corresponding to the 
pneumatic cylinders 72. In FIG. 6, the hook members 76 are movable only by 
manual engagement and manipulation of the levers 81 against the return 
force offered by the respective torsion springs 82. For convenience, the 
reference numeral 67 in FIG. 6 has been utilized to identify the hook 
supporting bracket 67 even though the bracket illustrated does not include 
the support extension 71. 
As illustrated in FIG. 3, the bulk bag 103 includes a plurality of handles 
104 thereon spaced around the top perimeter 106 of the bulk bag 103. A 
liner 107 is provided on the inside of the bulk bag 103. In this 
particular environment, both the bulk bag and the liner have an opening 
construction 108 at the upper end of both the bag and the liner and a 
further opening construction 109 at the bottom end of both the bulk bag 
103 and the liner 107. However, the opening construction 109 in the fill 
phase is closed but readily accessible when, for example, the bag is 
lifted, to facilitate an opening thereof as during an unloading of the 
contents from inside the liner 107. When the opening construction 109 is 
closed, and the opening construction 108 is connected to a conventional 
collar mechanism 111 surrounding a fill pipe 112, contents such as plastic 
pellets can be introduced into the interior of the liner 107 through the 
fill pipe 112. The collar mechanism 111 is an inflatable bladder-type 
securement ring which entraps the neck 110 of the liner in a conventional 
manner so as to prevent spillage of the material being placed into the 
liner 107. If desired, air can be introduced into the bag 103 or liner 107 
through an air intake 113 to inflate the bag 103 and liner 107 to minimize 
resistance to filling by the material of the bulk bag 103 and the liner 
107. Any dust that may exist during the filling process can be removed 
through a dust collecting outlet 114. If desire d, the dust collecting 
outlet can be connected to an exhaust system and a dust bag associated 
therewith. 
In use, a bag 103 and, if used, a liner 107 can be held lifted from the 
rollers 26 and/or a pallet 12 during filling. During filling, the bag 103 
can be lowered by operation of the motor 37, transmission 38 and lift 
mechanism 43 so that the bottom of the bag 103 rests on the rollers 26 or, 
if used, a pallet 12 or weighing device 116 and the tautness of the 
handles is diminished, so that they can be each released from the 
respective hook members 76. The hook member 76 at the second ends 89 of 
each elongated bar 63 is made particularly convenient to the operator when 
the respective hook supporting bracket 91 is movable toward the operator 
located adjacent the first ends 66. 
Although particular preferred embodiments of the invention have been 
disclosed in detail for illustrative purposes, it will be recognized that 
variations or modifications of the disclosed apparatus, including the 
rearrangement of parts, lie within the scope of the present invention.