U.S. patent application number 15/447475 was filed with the patent office on 2018-09-06 for bulk material container, sleeve and method of assembly.
The applicant listed for this patent is RMC Jones LLC. Invention is credited to Michael R. Jones, Robert J. Jones.
Application Number | 20180251284 15/447475 |
Document ID | / |
Family ID | 63294928 |
Filed Date | 2018-09-06 |
United States Patent
Application |
20180251284 |
Kind Code |
A1 |
Jones; Robert J. ; et
al. |
September 6, 2018 |
BULK MATERIAL CONTAINER, SLEEVE AND METHOD OF ASSEMBLY
Abstract
A collapsible bulk material container with a unique outer
support sleeve and method of manufacture thereof are disclosed. The
initial inner circumference of an oversized continuous woven
tubular support sleeve is adjustably sized to mattingly match the
outer peripheral circumference of a bulk material container forming
member which it is designed to support. One or more adjustment
tails are formed from the continuous sleeve material to accurately
reduce the initial inner sleeve circumference to an adjusted inner
circumference. The sizing operation can be performed during initial
manufacture of the sleeve or prior to assembly of the sleeve to the
forming member.
Inventors: |
Jones; Robert J.; (Prior
Lake, MN) ; Jones; Michael R.; (Apple Valley,
MN) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
RMC Jones LLC |
Prior Lake |
MN |
US |
|
|
Family ID: |
63294928 |
Appl. No.: |
15/447475 |
Filed: |
March 2, 2017 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
B31B 2105/0022 20170801;
B29L 2031/7126 20130101; B31B 2110/30 20170801; B29C 65/18
20130101; B65D 5/029 20130101; B65D 5/10 20130101; B29C 66/729
20130101; B65D 5/445 20130101; B65D 5/42 20130101; B65D 77/062
20130101; B65D 77/061 20130101; B29C 65/62 20130101; B65D 5/62
20130101; B29C 66/1122 20130101; B29C 66/7292 20130101; B29C 65/08
20130101; B29C 66/4312 20130101; B29C 66/71 20130101; B65D 5/106
20130101; B29C 66/73921 20130101; B31B 2120/501 20170801; B29C
66/71 20130101; B29K 2023/12 20130101 |
International
Class: |
B65D 77/06 20060101
B65D077/06; B65D 5/42 20060101 B65D005/42; B65D 5/10 20060101
B65D005/10; B65D 5/56 20060101 B65D005/56; B29C 65/08 20060101
B29C065/08; B29C 65/00 20060101 B29C065/00 |
Claims
1. An outer support sleeve of a type operable to snugly engage an
outer surface of a forming member of a bulk material container,
comprising: a. a continuously woven seamless tubular sleeve having
a sleeve length, longitudinally extending between opposed open
sleeve ends, and a sleeve initial inner circumference dimension; b.
a first longitudinally extending circumference adjustment tail
formed by said continuous sleeve material, extending along said
sleeve length; and c. said adjustment tail being formed by a
bonding strip extending along one longitudinal edge of said sleeve
when in a flattened configuration, with opposed inner surfaces of
said sleeve engaging one another in face to face relationship; said
bonding strip fixedly bonding said opposed engaged inner surfaces
of said sleeve to one another to accurately define an adjusted
inner circumference dimension of said sleeve that is less than said
initial sleeve inner circumference dimension.
2. The outer support sleeve of claim 1, wherein the sleeve material
is woven polypropylene material,
3. The outer support sleeve of claim 2, wherein the woven sleeve
material is impregnated with a coating of polypropylene
material.
4. The outer support sleeve of claim 1, wherein the bonding strip
comprises stitching.
5. The outer support sleeve of claim 1, wherein the bonding strip
comprises an ultrasonically formed weld bond.
6. The outer support sleeve of claim 1, wherein the bonding strip
comprises a hot melt formed bond.
7. The outer support sleeve of claim 1, further comprising: a. a
second longitudinally extending circumference adjustment tail of
said sleeve material, formed by the same bonding strip technique as
that of said first circumference adjustment tail; said second
circumference adjustment tail being diametrically oppositely
disposed across said flattened sleeve from said first circumference
adjustment tail; and b. said bonding strips of said first and said
second circumference adjustment tails in combination, accurately
defining said adjusted inner circumference dimension of said
sleeve.
8. The outer support sleeve of claim 7, wherein said first and said
second circumference adjustment tails each has a laterally measured
width measured from an inner edge of said bonding strip to an outer
longitudinal edge of said sleeve when in said flattened
configuration, of at least about 0.5 inches.
9. The outer support sleeve of claim 7, wherein said first and said
second circumference adjustment tails each has a laterally measured
width measured from an inner edge of said bonding strip to an outer
longitudinal edge of said sleeve when in said flattened
configuration, in a range of between about 0.25 inches to about
0.75 inches.
10. A container for bulk materials, comprising: a. a forming member
comprising a plurality of foldably interconnected sidewalls
extending between upper and lower edges and operative when folded
to cooperatively form and encircle an internal cavity for receiving
bulk materials; b. a locking assembly cooperatively engaging said
sidewalls to operatively define and fix the sidewalls in
predetermined relative positions, said locking assembly forming at
least in part, a bottom surface of said cavity; c. an outer tubular
support sleeve made of continuous woven seamless material, having a
sleeve length longitudinally extending between opposed open sleeve
ends, and having a sleeve initial inner circumference dimension,
further comprising: (i) a first longitudinally extending
circumference adjustment tail formed by said continuous woven
seamless sleeve material extending along said length of said
sleeve; and (ii) said adjustment tail being formed by a bonding
strip extending along one longitudinal edge of said sleeve when in
a flattened configuration, with opposed inner surfaces of said
sleeve engaging one another in face to face relationship; said
bonding strip fixedly bonding said opposed engaged inner surfaces
of said sleeve to one another to accurately reduce said sleeve
initial inner circumference dimension to an adjusted inner
circumference dimension; and d. said sleeve having said adjusted
inner circumference dimension being sized, arranged and configured
to operatively overlie and snugly engage substantially the entire
outer surfaces of said forming member sidewalls.
11. The container of claim 10, wherein the sleeve material is woven
polypropylene material.
12. The container of claim 11, wherein said woven sleeve material
is impregnated with a coating of polypropylene material.
13. The container of claim 10, wherein said bonding strip of said
sleeve comprises stitching.
14. The container of claim 10, wherein said bonding strip of said
sleeve comprises an ultrasonically formed weld bond.
15. The container of claim 10, wherein said bonding strip comprises
a hot melt formed bond.
16. The container of claim 10, wherein said sleeve further
comprises a second longitudinally extending circumference
adjustment tail of said continuous sleeve material, formed by the
same bonding strip technique as that of said first circumference
adjustment tail; said second circumference adjustment tail being
diametrically oppositely disposed across said sleeve from said
first circumference adjustment tail; wherein said bonding strips of
said first and said second circumference adjustment tails in
combination, accurately define said adjusted inner circumference
dimension of said sleeve.
17. The container of claim 10, further defined by: a. said forming
member comprising corrugated material having sidewalls that are
fixedly end-bonded together to form a peripheral wall continuously
encircling said internal cavity, wherein said sidewalls have a
nominal outer peripheral circumference dimension; and b. wherein
said adjusted inner circumference dimension of said sleeve is
substantially the same as said nominal outer peripheral
circumference dimension of said forming member sidewalls.
18. The container of claim 10, wherein said forming member
comprises corrugated material having sidewalls that are fixedly
end-bonded together to form a peripheral container wall, said
forming member being foldable-in-half prior to operative assembly
in 3-dimensional container form; and wherein said sleeve is
operatively engaged to overlie said forming member when said
forming member is in said folded-in-half configuration.
19. A method of manufacturing an outer support sleeve for a bulk
material container of the type having a forming member comprising a
plurality of foldably interconnected sidewalls extending between
upper and lower edges and operative when folded and held in place
by a locking assembly, to cooperatively form and encircle an
internal cavity for receiving bulk materials; wherein said outer
support sleeve is configured to snugly operatively overlie
substantially the entire outer surface area of said forming member
sidewalls to counteract radial forces exerted by bulk materials
within the container on the sidewalls, comprising the steps of: a.
weaving a continuous seamless open ended tubular sleeve of material
having a first inner sleeve circumference dimension; b. flattening
said tubular sleeve along its longitudinal length extending between
opposed open sleeve ends, such that juxtaposed upper and lower
inner portions of said flattened sleeve engage each other in face
to face relationship along said longitudinal length of said
flattened sleeve; c. fixedly bonding together said upper and lower
face to face engaged portions of said flattened sleeve material to
form a first bonding strip along a first longitudinal edge of said
flattened sleeve material, and a first adjustment tail of the
continuous sleeve material laterally extending outwardly from said
first bonding strip along said first longitudinal sleeve edge;
wherein an inner edge of said first bonding strip reduces said
first inner sleeve circumference dimension and defines an
accurately sized adjustment sleeve inner circumference dimension of
the sleeve material.
20. The method of claim 19, wherein said bonding step comprises
stitching said upper and lower engaged portions of said flattened
sleeve material along said first longitudinal edge of said
flattened sleeve material.
21. The method of claim 19, wherein said bonding step comprises
ultrasonically welding said upper and lower engaged portions of
said flattened sleeve material along said first longitudinal edge
of said flattened sleeve material.
22. The method of claim 19, including a step of fixedly bonding
together said upper and lower face to face engaged portions of said
flattened sleeve material, to form a second bonding strip along a
second longitudinal edge of said flattened sleeve material that is
diametrically opposed from and parallel to said first longitudinal
edge, and a second adjustment tail of the continuous sleeve
material laterally extending outwardly from said second bonding
strip along said second longitudinal sleeve edge; wherein inner
edges of said first and said second bonding strips along said first
and said second longitudinal edges of said flattened sleeve, in
combination with the inner surface of said sleeve material, define
said accurately sized adjusted sleeve inner circumference dimension
of said sleeve.
23. The method claim 19, wherein said tubular sleeve is woven from
polypropylene material.
Description
FIELD OF THE INVENTION
[0001] This invention relates generally to shipping and storage
containers for bulk materials, and more particularly to such
containers that use a tubular outer containment sleeve of flexible
woven fiber material that snugly overlies a forming member, and
which provides the primary containment strength for the
container.
BACKGROUND OF THE INVENTION
[0002] A general description of known configurations of bulk
material containers is detailed in the Background section of U.S.
Pat. No. 6,932,266 entitled COLLAPSIBLE BULK MATERIAL CONTAINER,
issued on Aug. 23, 2005. The U.S. Pat. No. 6,932,266 patent also
describes a number of embodiments of improved bulk material
container configurations, of the type to which the present
invention is specifically directed. The U.S. Pat. No. 6,932,266
Patent is fully incorporated herein by reference.
[0003] The bulk material containers of the general type described
in the U.S. Pat. No. 6,932,266 patent have been well received and
successful in the marketplace. They generally include a forming
member having a plurality of interconnected sidewalls that are
configurable to form a closed outer perimeter for a 3-dimensional
internal geometric volume of the container. Bottom edges of the
sidewalls are designed to be supported upon and carried by a
pallet. A locking mechanism or assembly is operatively connected
with the forming member sidewalls and maintains the forming member
sidewalls in predetermined positions relative to one another when
the container is empty. While the locking mechanism can be
physically separable from the sidewalls, it can also form a
physical extension of the sidewalls, as for example, a mechanism
that folds inwardly along the bottom edges of the sidewalls and
interconnects to form a bottom surface of the assembled container.
The locking assembly initially maintains the sidewalls in
predetermined fixed relationship to one another around the defined
internal geometric volume when operatively assembled, and prevents
the sidewalls from riding or sliding upward in a direction away
from the pallet or support surface for the forming member during
filling of the container. The forming member is typically
configured from a relatively light-weight corrugated material which
can, for example, be either of cellulose or plastic construction.
When configured as an extension of the forming member sidewalls,
the locking assembly can also be constructed from the same
corrugated material as the sidewalls. An outer open ended tubular
sleeve is sized to surround and snugly engage substantially the
entire outer peripheral wall areas of the forming member, and
assumes the defined geometric shape of the outer surface of the
forming member. The outer sleeve is preferably constructed of woven
polypropylene material and provides the necessary strength for
containing the bulk material within the forming member, while the
forming member provides the desired shape and transport rigidity
and stability for the bulk material container system. A standard
bag/liner can also be placed within the internal cavity defined by
the forming member as an impermeable membrane between the bulk
material and forming member, to protect bulk material of the
container from contamination or the environment, and/or to retain
liquids or flowable bulk materials within the internal cavity. Over
the time that such containers have been in the marketplace, they
have been used by a wide variety of customers for containing a
broad range of diverse bulk materials.
[0004] Since the overlying tubular sleeve material provides the
primary containment strength for a container of the type described,
a relatively thin or light-weight forming member can be used, which
reduces the cost of the container. The forming member's primary
function is to provide an outer peripheral shape for the container
that facilities loading of bulk material into the container and
provides a defined 3-dimensional container configuration that
enables container stackability and stability during transport. This
cooperative interrelationship between the forming member and the
outer sleeve requires the outer sleeve to snugly engage the outer
walls of the forming member, and to prevent the forming member from
expanding beyond its rupture tolerance as forces are applied to it
by the contained bulk material. This is particularly an issue
thereof when peripherally joined sidewalls of an operatively folded
forming member are glued together to form a generally inelastic
joint. Therefore, the inner circumference dimension of an outer
sleeve and the outer circumference dimension of the cooperating
forming member need to be within close tolerances of one another to
ensure a snug fit. The outer and inner circumference dimensions
respectively of the forming members and the outer sleeves are both
generally manufactured to the same nominal dimensions plus or minus
(+/-) a given tolerance. Random matching of forming members with
sleeves during assembly has been an issue in the manufacture and
assembly of such containers. For example, the forming member is
typically made from corrugated materials such as cardboard which
have low operative stretchability before rupturing, and can be
manufactured within fairly tight outer circumference tolerances. On
the other hand, the inner circumference manufacturing tolerances of
the outer sleeve have generally varied significantly more than the
tolerances of the forming member. Such sleeve tolerance variances
can cause an issue when, for example, an outer sleeve manufactured
to its maximum inside circumferential tolerance is matched in
operative overlying engagement with a forming member that is
manufactured to its minimum outer circumferential tolerance. In
such instances, the sleeve does not initially snugly engage the
outer surface of the forming member, which can lead to rupture of
the forming member as it expands from applied forces by the bulk
material before the overlying sleeve can fully counteract the
radial bulk material forces applied to and through the forming
member.
[0005] Recognizing this relative tolerance dilemma, assemblers of
the containers have been prone to use labor intensive, costly steps
of measuring and hand-sorting the outer sleeve and forming members
to cooperatively match the sleeves and forming members to be
assembled, according to their actual sizes. For example, those
forming members having a "minus" tolerance would be matched with
sleeves having a "minus" tolerance or nominal dimension, but not
with sleeves having a "plus" tolerance dimension. Similarly, those
forming members having a "plus" outer dimensional tolerance would
be matched with sleeves having a "plus" inner parameter tolerance
or a nominal dimension, but not with sleeves having a "minus"
dimensional tolerance. Such pre-assembly forming member and sleeve
sorting and matching operations are time consuming and costly
functions. Further, the preassembly sorting and matching of sleeves
and forming members generally makes the container assembly process
unsuitable for automation.
[0006] Since the forming members can generally be manufactured
within very small tolerances, the tolerance mismatch between
forming members and the outer sleeves is primarily caused by the
higher (+/-) tolerance ranges of the woven tubular outer sleeve.
The present invention provides an outer sleeve and a method of
manufacturing such sleeve that has an accurate inner circumference
that closely matches the nominal outer peripheral dimension of the
forming member, eliminating the costly and burdensome process of
pre-sorting and matching of sleeves to forming members, and
facilitates automation of the container assembly process.
SUMMARY OF THE INVENTION
[0007] This invention uses existing industry accepted packaging
materials to form a unique bulk container system that is
universally applicable to the packaging of solid, semi-solid,
granular or liquid materials. The bulk material container system of
this invention comprises the advantageous features of known
packaging techniques in a unique manner without suffering their
respective shortcomings. A forming member of relatively inexpensive
lightweight, generally corrugated, material has a plurality of
interconnected sidewalls that define an internal geometric
volumetric shape of the container in a manner that provides shape
to the container and structural support for enabling stacking of
loaded/filled containers. A locking assembly operatively connected
with the forming member, holds and locks the forming member
sidewalls in predetermined operative positions relative to one
another, to define a desired geometric volume and shape. The
locking assembly may comprise an extension of the forming member
and may form a bottom of the container when operatively assembled.
The forming member and locking assembly are collectively
collapsible for storage and transport and are easily erected by
folding into an operable box-like container configuration. The
assembled bulk container system is designed to be placed on and
carried by a pallet.
[0008] A tubular outer sleeve overlies and snugly engages
substantially the entire outer peripheral sidewall areas of the
forming member and operatively assumes the geometric shape of the
outer surface of the forming member. The outer sleeve is preferably
constructed of woven polypropylene material and provides the
primary bulk material containment strength for the container, while
the forming member provides the desired rigidity and shape to the
bulk material container system.
[0009] This configuration of a bulk material container provides an
advantage over conventional hard-walled containers, in allowing the
forming member to be constructed of relatively lightweight
material. However, it is important for the outer support sleeve to
snugly engage the forming member sidewalls, to prevent the
sidewalls from rupturing when large radial forces are applied to
them when bulk material is loaded into the internal cavity of the
container. The present invention provides a unique sleeve
construction and method of manufacture thereof, which enables the
sleeve to be manufactured to dimensional tolerances that closely
match those of the forming member to which the sleeve will be
applied, thereby assuring that the operative snug-fit requirement
between the forming member and the overlying sleeve will be
met.
[0010] According to one aspect of the invention, the outer sleeve
is continuously woven in tubular configuration with opposed open
ends so that it can be operatively slid in overlying engagement
with the forming member sidewalls. The outer sleeve is initially
woven to have an inside circumference dimension that is larger than
the nominal outer circumference dimension of the forming member,
referred to as the "nominal length", with which it will be mated.
The sleeve is then further processed by bonding opposing surfaces
of the sleeve along at least one longitudinal side of the sleeve in
a manner that reduces the initial oversized inner circumference of
the sleeve to an adjusted inner circumference dimension that
matches the nominal length dimension of the forming member with
which it will be operatively mated. The sleeve sizing operation can
be readily incorporated into and form an operative step of an
assembly line operation in which the tubular sleeve is formed, or
can be later performed prior to the container assembly step of
applying the sleeve to the forming member.
[0011] According to one aspect of the invention, there is provided
an outer support sleeve of a type operable to snugly engage an
outer surface of a forming member of a bulk material container,
comprising: (a) a continuously woven tubular sleeve having a sleeve
length, longitudinally extending between opposed open ends, and a
sleeve initial inner circumference dimension; (b) a first
longitudinally extending circumference adjustment tail of the
continuous sleeve material, extending along the length of the
sleeve; and (c) wherein the tail is formed by a bonding strip
longitudinally extending along one edge of the sleeve when in a
flattened configuration, with opposed surfaces of the sleeve
engaging one another, wherein the bonding strip fixedly bonds the
opposed engaged surfaces of the sleeve to one another in a manner
which accurately defines an adjusted inner circumference dimension
of the sleeve that is less than the initial sleeve inner
circumference dimension. According to a further aspect of the
invention, the outer support sleeve is constructed of woven
polypropylene material. The woven sleeve material can also be
impregnated with a coating of polypropylene material to provide a
liquid barrier.
[0012] According to one aspect of the invention, the sleeve bonding
strip comprises stitching. According to another aspect of the
invention, the bonding strip could comprise an ultrasonically
formed weld bond or could also comprise a hot melt formed bond.
[0013] According to a further aspect of the invention, the outer
support sleeve includes multiple circumference adjustment tail
configurations. For example, the outer support sleeve could further
comprise: (a) a second longitudinally extending circumference
adjustment tail of the sleeve material, formed by the same bonding
strip technique as that used to form the first circumference
adjustment tail, wherein the second circumference adjustment tail
is positioned diametrically oppositely disposed across the
flattened sleeve from the first circumference adjustment tail; and
(b) wherein the bonding strips of the first and second
circumference adjustment tails, in combination, accurately define
the adjusted inner circumference dimension of the sleeve. According
to yet a further aspect of the invention, the first and/or second
circumference adjustment tails each has a laterally measured width
as measured from an inner edge of its bonding strip to an outer
longitudinal edge of the sleeve when in its flattened
configuration, of about at least 0.5 inches. According to yet a
further aspect of the invention, the first and second circumference
adjustment tails each have a laterally measured width as measured
from an inner edge of its bonding strip to an outer longitudinal
edge of the sleeve when in its flattened configuration, in a range
of between about 0.25 inches to about 0.75 inches.
[0014] According to yet a further aspect of the invention, there is
provided a container for bulk materials, comprising: (a) a forming
member comprising a plurality of foldably interconnected sidewalls
extending between upper and lower edges and operative when folded
to cooperatively form and encircle an internal cavity for receiving
bulk materials; (b) a locking assembly cooperatively engaging the
sidewalls to operatively define and fix the sidewalls in
predetermined relative positions, wherein the locking assembly
forms in part, a bottom surface of the cavity; (c) an outer tubular
support sleeve made of continuous woven material, having a sleeve
length longitudinally extending between opposed open ends and
having a sleeve initial inner circumference dimension, further
comprising: (i) a first longitudinally extending circumference
adjustment tail of the continuous sleeve material, extending along
the length of the sleeve; and (ii) wherein the sleeve is formed by
a bonding strip longitudinally extending along one edge of the
sleeve when in a flattened configuration, with opposed surfaces of
the sleeve engaging one another; wherein the bonding strip fixedly
bonds the opposed engaged surfaces of the sleeve to one another to
accurately reduce the sleeve initial inner circumference dimension
to an adjusted inner circumference dimension; and (d) wherein the
sleeve having the adjusted inner circumference dimension being is
sized, arranged and configured to operatively overlie and snugly
engage substantially the entire outer surfaces of the forming
member sidewalls.
[0015] Accordingly to a further aspect of the invention, the sleeve
of the above-described container comprises woven polypropylene
material. According to yet a further aspect of the invention, the
woven sleeve material is impregnated with a coating of
polypropylene material to make the material impervious to liquid
penetration. According to yet a further aspect of the invention,
the bonding strip of the sleeve comprises stitching. According to
yet a further aspect of the invention, the bonding strip of the
sleeve comprises an ultrasonically formed weld bond or a hot melt
formed bond.
[0016] According to yet a further aspect of the invention, the
sleeve of the above-described container further comprises a second
longitudinally extending circumference adjustment tail of the
continuous sleeve material, formed by the same bonding strip
technique as that of the first circumference adjustment tail,
wherein the second circumference adjustment tail is diametrically
oppositely disposed across the sleeve from the first circumference
adjustment tail, and wherein the bonding strips of the first and
the second circumference adjustment tails in combination accurately
define the adjusted inner circumferent dimension of the sleeve.
[0017] According to yet a further aspect of the invention, the bulk
material container forming member comprises corrugated material
having sidewalls that are fixedly end-bonded together to form a
peripheral wall continuously encircling the internal cavity of the
container, wherein the sidewalls have a nominal outer peripheral
circumference dimension; and wherein the adjusted inner
circumference dimension of the sleeve is substantially the same as
the nominal outer peripheral circumference dimension of the forming
member sidewalls. According to yet a further aspect of the
invention, the fixedly end-bonded together sidewalls of the forming
member can be folded-in-half prior to operative assembly in
3-dimensional container form, and the sleeve can be operatively
engaged to overlie the forming member while the forming member is
configured in its folded-in-half configuration.
[0018] According to yet a further aspect of the invention there is
provided a method of manufacturing an outer support sleeve for a
bulk material container of a type having a forming member
comprising a plurality of foldably interconnected sidewalls
extending between upper and lower edges and operative unfolded and
held in place by a locking assembly to cooperatively form and
encircle an internal cavity receiving bulk materials, wherein the
outer support sleeve is configured to snugly operatively overlie
substantially the entire outer surface area of the forming member
sidewalls to counteract radial forces exerted by bulk materials
within the container on the sidewalls, comprising the steps of: (a)
weaving a continuous open-ended tubular sleeve of material having a
first inner sleeve circumference dimension; (b) flattening the
tubular sleeve along its longitudinal length such that opposed
upper and lower portions of the flattened sleeve engage each other
across their flattened length; (c) fixedly bonding together the
upper and lower engaged portions of the flattened sleeve material
to form a first bonding strip along a first longitudinal edge of
the flattened sleeve material, and a first adjustment tail of the
continuous sleeve material laterally extending outwardly from the
first bonding strip along the first longitudinal sleeve edge;
wherein an inner edge of the first bonding strip reduces the first
inner sleeve circumference dimension and defines an accurately
sized adjustment sleeve inner circumference dimension of the sleeve
material. According to yet a further aspect of the method of the
manufacturing the outer support sleeve, the bonding step could
comprise stitching the upper and lower engaged portions of the
flattened sleeve material along the first longitudinal edge of the
flattened sleeve material, or alternatively could comprise an
ultrasonic welding bonding step or a hot melt bond forming
step.
[0019] According to yet a further aspect of the invention, the
method of manufacturing an outer support sleeve as described above
can further include a step of fixedly bonding together the upper
and lower engaged portions of the flattened sleeve material to form
a second bonding strip along a second longitudinal edge of the
flattened sleeve material that is diametrically opposed from and
parallel to the first longitudinal edge, and a second adjustment
tail of the continuous sleeve material laterally extending
outwardly from the second bonding strip along the second
longitudinal sleeve edge, wherein inner edges of the first and
second bonding strips along the first and second longitudinal edges
of the flattened sleeve, in combination, define the accurately
sized adjusted sleeve inner circumference dimension of the sleeve.
According to yet a further aspect of the method of manufacturing
the tubular sleeve, the material used to weave the sleeve could
comprise polypropylene material.
[0020] Typically, in manufacturing the outer sleeve, the tubular
sleeve is continuously formed and passes along an assembly line of
operations wherein strategic markings and/or graphics and/or
lettering and instructions are printed upon at least the outer
surface of the sleeve. The sleeve can also be subjected to steps
that form strategically located connector receptor slots or other
connecting mechanisms for cooperatively engaging portions of the
forming member or locking assembly portions of the container. The
completed tubular sleeve material can be rolled into a cylindrical
roll for shipping to a container assembly facility where the roll
will be cut into individual sleeves for overlying a forming member
of individual containers. Alternatively, the tubular side-bonded
sleeve material can be cut into individual container sleeve lengths
on the sleeve assembly line and bundled for shipment to an
assembler. Alternatively, if the entire sleeve and forming member
assembly is performed at the same facility, the tubular side bonded
sleeve material can be slid over folded-in-half end-bonded forming
members, and cut to length before or after operative application of
the sleeve to the forming member.
[0021] Typically, however, the sleeve material will be shipped
after printing and other marking operations either in roll or
cut-to-length bundles to another facility for application to
completed forming members. The completed forming members/locking
assembly and applied sleeve units are then bundled for subsequent
shipment to end users.
[0022] Besides providing a mechanism for accurately adjustably
matching the inner circumference of the sleeve to the outer
peripheral circumference of a sleeve to the outer peripheral
circumference of a forming member, the adjustment tails of the
sleeve provide mechanical gripping means for facilitating manual
and/or automated assembly of a sleeve to a forming member.
[0023] These and other features of the invention will become
apparent from a more detailed description of preferred embodiments
of the invention as described below.
BRIEF DESCRIPTION OF THE DRAWING
[0024] Referring to the Drawing, wherein like numerals represent
like parts throughout the several views:
[0025] FIG. 1 is an exploded perspective view of one embodiment of
a bulk material container assembly applicable to the present
invention, and having a forming member, a shape defining locking
assembly, an outer sleeve member and an optional bag/liner;
[0026] FIG. 2 is a view illustrating on a planar sheet, a pattern
and folding configuration of the forming member and locking
assembly of the bulk material container assembly of FIG. 1;
[0027] FIG. 3 is a view of one side of the forming member and
locking assembly of FIG. 2 as it would appear when folded upon
itself along the folding lines 30c and 30g of FIG. 2, with the
opposite or back side thereof not shown;
[0028] FIG. 4 is an view of the folded forming member and locking
assembly of FIG. 3, as viewed from the opposite side thereof, and
with the back side thereof not shown;
[0029] FIG. 5 is a diagrammatic pictorial view of an outer sleeve
member of the bulk material container assembly of FIG. 1,
illustrating circumferentially spaced receptor slots formed through
the sleeve material adjacent the lower end thereof;
[0030] FIG. 6 is a bottom diagrammatic view of the forming member
and locking assembly of FIGS. 2-4 illustrating the locking assembly
segments folded inwardly and interlocked to form a closed bottom
locking configuration for the container that locks the sidewalls of
the forming member in fixed relative spaced positions;
[0031] FIG. 7 is a pictorial bottom/side perspective view of the
bulk material container during assembly, illustrating the bottom
portion of the sleeve positioned in an extended manner below the
general plane of the assembled locking assembly bottom of the
container as it would appear prior to folding it inwardly against
and operatively connecting it to sleeve retaining tab members of
the locking assembly;
[0032] FIG. 8 is a pictorial bottom/side perspective view of a
completed assembly of the bulk material container of FIG. 7,
illustrating the sleeve folded against the bottom of the container
with its lower receptor slots operatively engaging and connected to
the sleeve retaining tab members of the locking assembly and with
excess sleeve material at the bottom corners of the forming member
tucked into and retained within sleeve retaining gap portions of
the locking assembly;
[0033] FIG. 9A is a diagrammatic pictorial view of one embodiment
of an outer sleeve member for a bulk material container, configured
according to this invention, having an adjustment tail portion with
an included stitched bonding strip longitudinally extending along
one side of the sleeve member;
[0034] FIG. 9B is an enlarged fragmentary view of a corner end
portion of the outer sleeve member of FIG. 9A that is enclosed
within the dashed Circle A-A of FIG. 9A;
[0035] FIG. 10A is a diagrammatic pictorial view of a second
embodiment of an outer sleeve member for a bulk material container,
configured according to this invention, having a pair of spaced
adjustment tail portions each including a stitched bonding strip
longitudinally extending along opposite sides of the sleeve member;
and
[0036] FIG. 10B is an enlarged fragmentary view of the upper end
portion of the outer sleeve member of FIG. 10A that is enclosed
within the dashed Lines B-B of FIG. 10A.
DETAILED DESCRIPTION
[0037] One embodiment of a bulk material container assembly of the
type to which the present invention applies is described below with
reference to FIGS. 1-8. Descriptions of alternative bulk material
container embodiments, of their use and construction, of the
materials that are usable to construct the container assemblies,
and other alternatives applicable to the invention are described
more fully in U.S. Pat. No. 6,932,266 which is fully incorporated
herein by reference.
[0038] Referring to FIG. 1, a bulk material container assembly is
generally illustrated at 20. For ease of description, the bulk
material container assembly will hereinafter be referred to as "the
container". The container 20 generally includes a forming member
22, a locking assembly or mechanism 24, an outer support sleeve 26
and an optional inner liner 28. The forming member 22 provides a
defined geometric shape and structural stability to the container,
while the sleeve 26 is sized to cooperatively and snugly engage and
circumferentially surround at least substantially the entire outer
surface area of the forming member sidewalls 22, and provides the
primary bulk material containment strength for the container. The
optional inner bag/liner 28 is generally placed within the forming
member 22 and directly contacts the bulk material, to protect the
container contents from contamination and/or to retain flowable or
liquid contents from leaving or leaking out of the container.
[0039] The forming member 22 is preferably configured from a
relatively light-weight corrugated material which can, for example,
be either of cellulose or plastic construction. The forming member
is folded along a plurality of fold lines to form a plurality of
adjoining upright sidewalls configured to form a closed perimeter
shell as shown in FIG. 1. Closed perimeter forming member sidewalls
define with a lower surface, an internal geometric volumetric shape
23 that defines a bulk material storage portion of the container.
The bottom edges of the forming member sidewalls are designed to be
supported and carried by a pallet. While a pallet can contain more
than one bulk container, typically the container is sized and
configured to be carried by a single pallet. The locking mechanism
maintains the forming member sidewalls in predetermined upright
fixed position relative to one another when a container is empty.
While the locking mechanism can be physically separated from the
sidewalls, in the embodiment illustrated in FIGS. 1-8, the locking
mechanism or assembly comprises lower extension portions of the
forming member's sidewalls, generally illustrated at 24 in FIG. 2.
The lower extension locking portions 24 of the sidewalls fold
inwardly along the bottom edges 32 of the sidewalls and overlap and
interconnect with one another to fix and maintain the forming
member sidewalls in predetermined spaceal relationship with one
another when operatively assembled, around the defined internal
geometric volumetric shape 23. The interlocking lower locking
assembly portions 24, when operatively assembled, also form and
define a bottom surface of the container. Besides fixing the
geometric footprint formed by the sidewalls, the locking assembly
also prevents the sidewalls from riding or sliding upwardly, away
from the bottom of the forming member during filling or
transporting of the container. For additional details, description
of materials and design considerations relating to bulk material
containers of the general type described above, the reader is
referred to U.S. Pat. No. 6,932,266.
[0040] Referring to FIG. 2, a patterned substrate of an integrally
connected forming member 22 and locking assembly 24 is illustrated
as it would appear in plannar form after being die cut and scored
for folding lines, from a sheet of corrugated material such as
cardboard. In the embodiment illustrated the substrate is made of
corrugated 0.25 inch think cardboard. The substrate shown is scored
along vertical fold lines 30a-30h that divide the forming member 22
into eight adjacent and integrally connected sidewalls 22a -22h.
The sidewalls 22 extend between an upper edge 31 to the horizontal
lower fold line 32, which also defines the upper boundary (as shown
in FIG. 2) of the integrally connected locking assembly member
projections 24a -24h. Locking assembly member projections 24a -24h
continuously extend respectively from the sidewalls 22a -22h, and
are joined thereto along the horizontal fold line 32. When the
corrugated material which forms the forming member sidewalls 22 and
the locking mechanism extensions 24 of the sidewalls 22 are folded
along the fold lines 30 and 32 and interconnected to form the
octagon shaped forming member configuration 22 of FIG. 1, the
material at the fold line 32 defines the lower edges of the forming
member sidewall segments 22a -22h, as well as the upper edges of
the locking member projections 24a -24h that interconnect to form
the locking mechanism of the container 20. The locking assembly
members 24c and 24g also include secondary horizontal folding lines
32a and 32b, as illustrated in FIG. 2, that allow selective folding
of portions of the locking assembly members 24c and 24g which
facilitate interconnection of the locking members during assembly
of the container. The two end sidewalls 22a and 22h each has a
vertical bonding strip portion, generally designated at the
cross-hatched portions 33. The bonding strip portions 33 are sized,
shaped and configured to overlap with and to be glued to one
another when the forming member is operatively folded along the
vertical fold lines 30a-30h, to operatively form a peripherally
continuous 3-dimensional forming member as generally illustrated in
FIG. 1.
[0041] In the embodiment illustrated, the forming member 22 as
above described is folded-in-half and glued together along the
vertical bonding strips 33, to form a bonded continuous relatively
inelastic outer peripheral wall surrounding the internal geometric
volume 23 that will hold the bulk material. Such configuration is
preferred over other designs of forming members such as described
in, for example, U.S. Pat. No. 6,932,266 which describes several
embodiments of forming members incorporating a slidable
interconnection of the opposed interconnected ends of the forming
member. The glued configuration of the forming member is preferred
over such slidably interconnected forming member, since the rigid
bonding of the glued together ends of the forming member enables
the assembled member to better maintain its 3-dimensional shape
which results in better stacking and transport stability of a
loaded bulk container.
[0042] FIGS. 3 and 4 illustrate views from opposite sides of the
forming member and connected locking assembly of FIG. 2, as they
would appear when its bonding strips 33 are fixedly glued to one
another to form a continuous ring, and when the substrate is
folded-in-half upon itself along the folding lines 30c and 30g. The
gluing operation, to fixedly bond the vertical bonding strips 33 to
one another may be performed at the same manufacturing facility
that produces the die cut plannar substrate of FIG. 2, or may be
performed at subsequent assemblies or at end user facilities.
Accordingly, the combined forming member/locking assembly may be
bundled and shipped between assembly facilities and/or end users in
plannar substrate form as in FIG. 2, in glued, folded-over
configuration as in FIGS. 3 and 4, or in glued folded-over
configuration with attached sleeve.
[0043] The locking assembly members 24 (of FIG. 2) are described in
more detail with respect to FIGS. 3 and 4. Referring thereto, the
locking member extensions segment 24a and 24e are configured to
cooperatively engage one another during assembly of the container
to its open 3-dimensional configuration as illustrated in FIG. 1.
Referring to FIG. 4, the locking segment 24a is shown as extending
between its proximal connection to the sidewall 22a along the fold
line 32, and a distal end D1. The distal end D1 is configured to
define a primary tab receptor slot 24a.1 and a pair of projecting
tab portions T1 and T2, extending distally outward from the locking
segment 24a on opposite sides of the primary tab receptor slot
24a.1. The locking segment 24a also has oppositely disposed side
edges S1 and S2. Each of the side edges S1 and S2 has an outwardly
projecting sleeve retaining tab member 35.
[0044] Referring to FIG. 3, the locking segment 24e is shown
extending between its proximal connection to the sidewall 22e along
the fold line 32, and a distal end D2. The distal end D2 is
configured to define a primary tab 24e.1 outwardly projecting from
the distal end D2, and a pair of tab receptor seat portions R1 and
R2, spaced inwardly back from the distal end of the primary tab
24e.1 of the locking segment 24e, on opposite sides of the primary
tab 24e.1. The locking segment 24e also has oppositely disposed
side edges S3 and S4. Each of the side edges S3 and S4 has an
outwardly projecting sleeve retaining tab member 35 of the same
configuration as the same numbered sleeve retaining tab members of
the locking segment 24a of FIG. 4.
[0045] The locking segment 24a has a pair of laterally aligned and
spaced, oppositely angled tab receptor slots TRS1 and TRS2, spaced
back from the distal end D1 of the locking segment 24a. Similarly,
the locking segment 24e has a pair of laterally aligned and spaced,
oppositely angled tab receptor slots TRS3 and TRS4, spaced back
from the distal end D2 of the locking segment 24e. When the folding
member 22 and locking assembly are operatively assembled in bulk
container configuration, the locking member extensions 24a and 24e
operatively interconnected with one another. The primary tab 24e.1
of the locking member portion 24e cooperatively slides within the
primary tab receptor slot 24a.1 of the locking member portion 24a,
and the projecting tab portions T1 and T2 of the locking member
portion 24a cooperatively overlie the pair of tab receptor seat
portions R2 and R1 respectively to maintain the distal end portions
D1 and D2 of the locking member portions 24a and 24e respectively
in operative engagement with one another.
[0046] The locking member extension portions 24c and 24g are
identically shaped. Referring to FIGS. 3 and 4, the locking
segments 24c and 24g are shown as extending between their proximal
connection to the sidewalls 22c and 22g respectively along the fold
line 32, and their respective distal ends D3 and D4. The locking
segments 24c and 24g each has a primary tab portion T3 and T6
respectively, extending distally outward from the central portion
of their respective locking segments. The locking segment 24c has a
pair of projecting tab portions T4 and T5 extending distally
outward from the locking segments 24c on opposite sides of the
centrally located primary tab T3. Similarly, the locking segment
24g has a pair of projecting tab portions T7 and T8 extending
distally outward from the locking segments 24g on opposite sides of
its centrally located primary tab T6. During assembly of the bulk
container into operative position, the locking segments 24c and 24g
are folded along the fold line 32 inwardly toward one another. Both
of the locking segments 24c and 24g partially orthogonally overlap
the locking segments 24a and 24e, from opposite directions, and
form a locking relationship with the locking segments 24a and 24e
as follows. The projecting tabs T4 of locking segment 24c, and T8
of locking segment 24g cooperatively respectively retainably engage
the tab receptor slots TRS 4 and TRS 3 of the locking segment 24e
in locking manner. The projecting tab T5 of locking segment 24c,
and T7 of locking segment 24g respectively cooperatively retainably
engage the tab receptor slots TRS1 and TRS2 of the locking segment
24a in locking manner. Each of the oppositely disposed side edges
of the locking member segments 24c and 24g also includes an
outwardly projecting sleeve retaining tab member 35 of the same
configuration and construction as those sleeve retaining tab
members of like number of the locking segments 24a and 24e,
previously described.
[0047] The identically shaped sidewall lower extension segments
24b, 24d, 24f and 24h are included within the designation of
"locking assembly segments" since they share a common physical
location below the lower fold line 32, and are cooperatively
inwardly folded along with the other locking assembly segments
previously described, to collectively define therewith the
3-dimensional shape of the container. It will be noted that even
though the lower extension segments 24b, 24d, 24f and 24h, referred
to as "locking" segments, cooperatively sidably engage others of
the locking assembly segments, they do not include any specific
"interlocking" mechanisms like, for example, those of locking
segments 24a, 24c, 24e and 24g previously described.
[0048] In the embodiment illustrated, the length (in the horizontal
direction as illustrated in FIGS. 3 and 4) of the folded-in-half
and glued forming member configuration, is 72 inches, and the
combined height (measured in the vertical direction of FIGS. 3 and
4) of the forming member and locking assembly segments, is 66
inches. The total operative length of the plannar unfolded
substrate illustrated in FIG. 2 is 144 inches as measured from the
folding line 30h on the left, to the right edge of the forming
member segment 22a. These dimensions are for a relatively large
bulk material container that would occupy, when operatively
unfolded, virtually the entire surface area of a 40 inch by 48 inch
pallet, which is an industry standard pallet size for certain
industries such as the meat packing industry. The container, and
thus the forming member sizes, generally dictated not only by the
nature and type of bulk materials to be loaded into the container,
but also by the industry standardized sizes of the pallets that
will be used in the various industries to move and transport the
containers. Accordingly, the size and outer peripheral shapes of
the containers can vary widely from, for example, smaller
folded-in-half and glued forming member configurations having
lengths of 36 to 40 inches, all the way up to larger containers
such as that illustrated in the embodiment disclosed above, of 72
or more inches.
[0049] The outer support sleeve 26 is preferably constructed of the
same types of materials well-known in the art, that are used for
making flexible intermediate bulk containers (FIBCs). The sleeve is
preferably woven from flexible fiber materials, preferably
polypropylene materials, which are known for their strength and
lightweight. The sleeve 26 of known bulk material containers forms
a continuous tubular open ended and seamless sleeve requiring no
sewing or stitching such as illustrated in FIG. 5. After weaving,
the sleeve material may be impregnated with a polypropylene
coating, which adds further strength to and waterproofs the woven
material. As initially woven, the open ended tubular sleeve is
generally of cylindrical configuration around a central axis.
However, when operatively slid over a forming member, the sleeve
assumes the geometric configuration of the outer peripheral walls
of the forming member. The sleeve is generally slid over the
forming member when it is configured in the flattened
folded-in-half configuration as illustrated in FIGS. 3 and 4, which
is generally rectangular in shape. However, when the forming member
is opened to define an internal geometric volume within its
sidewalls, the outer peripheral shape of the forming member, and
the thus the shape of the overlying sleeve changes to its operative
designed shape, such as the octangular shape illustrated in the
disclosed container embodiment.
[0050] The sleeve is typically manufactured by an entity other than
those providing the forming member/locking assembly configurations,
both of which may be different from the entity finally assembling
the bulk container for operative use. A plurality of sleeves may be
packed in a continuous roll of sleeves which require separation at
the point of the container assembly. The sleeve material can simply
be cut to a desired length by a shear, by laser, or by a hot knife
technique that also conditions the woven material along the cut to
prevent unraveling thereof Alternatively, the individual sleeves
may be cut to their desired lengths at their point of manufacture,
and bundled for shipment to an assembler of the container. The
sleeve is preferably cut to a length that will cover virtually the
entire outer peripheral surface of the forming member sidewalls and
to extend slightly below the lower edge 32 of the assembled forming
member, for folding inwardly below and in engagement with the
locking assembly 24, as hereinafter described.
[0051] FIG. 5 is a diagrammatic pictorial view of a sleeve, which
extends from an upper edge 26a to a lower edge 26b. The "length" of
the sleeve, as discussed above, is measured between its upper 26a
and lower 26b edges. In the embodiment illustrated in FIG. 5, the
sleeve includes a plurality of circumferentially spaced generally
vertical slits 40 adjacent to but vertically spaced from the lower
edge 26b of the sleeve 26. The vertical slits 40 are preferably cut
through the polycoated sleeve's surfaces and woven material with a
hot blade or wire, that results in no unraveling of the exposed
sleeve threads along the slit edges, in a manner well recognized by
those skilled in the art. The slits are vertically located within
the circumferential strip of sleeve material designated at 26c in
FIG. 5, which extends approximately 10 inches downwardly below the
fold line 32 defining the lower edge of the forming member 22 when
the sleeve is operatively slidably engaged with the forming member.
In the embodiment illustrated, the sleeve material 26c that extends
below the fold line 32 is configured to be operatively folded
inwardly and into engagement with the bottom surfaces of the
locking members 24 when the container is fully assembled. In the
embodiment illustrated, the slits 40 are sized, shaped and
positioned to cooperatively and retainably engage opposed pairs of
the sleeve retaining tab members 35 of the locking assembly
segments, to maintain the sleeve in its desired position overlying
the forming member and to prevent the sleeve from arising up along
the outer sidewalls of the forming member during assembly, handling
and loading of the container.
[0052] An assembler of the container typically receives the forming
member/locking assembly in a folded-in-half condition as shown in
FIGS. 3 and 4, with the distal ends of the forming member sidewalls
22a and 22h already bonded together by the vertical bonding strips
33. The sleeve may or may not already have been applied to the
folded forming member/locking assembly configuration. If the sleeve
26 is not yet been applied to the container, it is pulled over the
collapsed forming member 22/locking assembly 24 configuration,
typically starting at the upper edge 31 of the forming member 22
and sliding the sleeve downwardly over the forming member until the
leading (bottom) edge 26b of the sleeve 26 extends below the lower
fold line 32 of the forming member 22 by the distance or length
generally illustrated at 26c (FIG. 5) and until the top edge 26a of
the sleeve coincides with or is positioned slightly below the upper
edge 31 of the forming member. This step may also have previously
been performed by the sleeve or forming member manufacturer, or by
a subsequent pre-assembler who then ships the forming
member/locking assembly with attached sleeve to the ultimate end
assembler of the bulk container. The excess sleeve material 26c
adjacent the bottom edge of the sleeve is intended and configured
to be folded under the bottom of the assembled bulk container as
hereinafter described.
[0053] To configure the bulk container into a 3-dimensional shape,
the forming member/locking assembly as shown in FIGS. 3 and 4, with
overlying sleeve 26 as previously described, is inverted from that
position shown in FIGS. 3 and 4 and placed on a generally planar
support surface with the upper edge 31 of the forming member
resting on the support surface. The sidewalls 22 are pulled apart
from their folded-in-half configuration in a manner to fold the
respective sidewalls along their vertical fold lines 30a-30h so as
to define an internal geometric solid shaped cavity 23 formed by
the peripherally connected inner sidewall surfaces. In the
embodiment illustrated, the formed cavity 23 will have a generally
octagonal shape due to the fact that the forming member has eight
sidewall segments 22a -22h. In such position, the locking assembly
segments 24 will extend in an upward direction from the inverted
sidewalls 22. The locking assembly segments 24 are then folded
along the horizontal fold line 32 in inward directions toward the
cavity and interlocked to fix and lock the geometrical perimeter
shape of the sidewalls.
[0054] The first segments of the locking mechanism to be inwardly
folded are the four identically shaped segments 24b, 24d, 24f and
24h. When folded inwardly toward the center of the container these
segments form the innermost members of the bottom of the container
and of the enclosed internal geometric volume 23. Next, the opposed
locking segments 24a and 24e are folded inwardly toward one another
until their distal ends D1 and D2 respectively cooperatively
retainably engage one another near the center of the container,
with the primary tab 24e.1 of segment 24e being cooperatively
received by the primary tab receptor slot 24a.1 of the segment 24a.
The outer tab members T1 and T2 of locking segment 24a are
cooperatively respectively engaged by and slide under the tab
receptor seat portions R2 and R1 of locking segment 24e.
[0055] The final two locking segments 24c and 24g are then folded
inwardly toward each other and respectively interlock with the
underlying locking segments 24a and 24e. When interlocked, the
outer tab portions T4 and T5 of locking member 24c cooperatively
retainably slide within the and are retained by the tab receptor
slots TRS 4 and TRS 1 respectively, and the outer projecting tabs
T7 and T8 of the locking member 24g are cooperatively received and
retainably held by the tab receptor slots TRS 2 and TRS 3
respectively. Bottom views of the assembled locking segments are
shown in FIGS. 6 and 7. FIG. 6 is a bottom plan view of the
completed locking assembly, and FIG. 7 is a perspective bottom and
side view of the partially assembled bulk container 20 illustrating
the outer sleeve portion 26c extending upwardly beyond the general
plane of the interlocked locking assembly segments 24, as it might
appear immediately before folding toward and against the
interconnecting assembly segments 24. As shown in FIG. 6, the
overlapping and interconnected locking member 24 form vertical
gaps, generally depicted at 27 between the first folded corner
segments 24b, 24d, 24f and 24h and the overlying locking member
segments 24a, 24c, 24e and 24g, into which portions of the
folded-over sleeve 26c can be tucked.
[0056] The final assembly step is to sequentially fold inwardly the
sleeve portion 26c extending beyond the bottom edge 32 of the
forming member sidewalls (FIGS. 6, 7 and 8). For the embodiment
illustrated, as each of the sleeve portions 16c are sequentially
folded inwardly over the bottom edge 32 of the sidewalls 22a, 22c,
22e, and 22g, they are pulled by their longitudinally spaced ends
into taut engagement with the underling locking segments 24a, 24c,
24e, and 24g respectively in a manner such that the spaced slits 40
of the folded sleeve portion 26c cooperatively align with and
slidably retainably engage the opposed sleeve engagement tab 35
respectively of the locking segments 24a, 24c, 24e or 24g with
which they are aligned. The sleeve engagement tabs 35 thereafter
retainably hold the sleeve 26 in locked engagement with the bottom
of the container during subsequent handling and movement of the
container, and thereafter during loading and transport. When the
side portions of the lower sleeve portion 16c are tautly secured to
the sleeve engagement tabs 35, excess sleeve material 16c naturally
bunches up near the corners of the container adjacent the locking
assembly formed gaps 27 (FIG. 6). Such excess sleeve material is
readily folded and tucked into the gaps 27 and retainably held
within the gaps in sandwiched positioned between the locking member
segments forming the gaps. A bottom and side perspective view of
the completed assembled bulk container is shown in FIG. 8.
[0057] Upon completion of the container assembly, the container can
be inverted back to its upward position as shown in FIG. 1, for
placement on a pallet and subsequent loading of bulk material. As
bulk material is loaded into the container, the weight of the
material applies increasing downward pressure to the bottom of the
container and locking assembly, compressing the gaps 27 to even
more tightly secure the sleeve material 16c in place to and under
the container. The increasing retaining pressure applied to the
secured sleeve under the container, counteracts the increased
radial pressure applied to the sleeve that tries to pull the sleeve
upward along the outer sidewalls of the forming member, providing
extra strength and stability to the container.
[0058] When bulk material is loaded into the internal cavity of the
forming member, the resultant downward and horizontal (radial)
applied pressure from the bulk material against the forming member
sidewalls is very large. Further, the outward radial pressure is
largest near the lower third of the sidewalls. The outer sleeve is
sized and configured to support the majority of the radial outward
forces inserted by the bulk material to the forming member.
However, to effectively do so, the outer sleeve must "snugly"
engage the outer circumferential surface of the forming member so
that it can immediately assume it's function of operatively
containing the radial forces applied by the bulk material to the
container walls. Since an end-glued forming member like that
illustrated in FIGS. 2-4 is a rigid walled configuration
surrounding the internal cavity 23 having little elasticity, and
since a design benefit of the described type of forming member is
that a fairly light-weight and less expensive forming member
material can be utilized, if the outer sleeve does not
substantially snugly engage substantially all of the outer surface
areas of the forming member, the forming member material may be
forced to expand beyond its rupture limit. Such rupture can
decrease the effectiveness of the primary purposes for which the
forming member is designed--to provide the structural shape and the
majority of the rigidity and stackability and transport stability
to the bulk container system. While the sleeve material is of
sufficient strength to accept and counteract all of the radial
forces applied through the forming member whether or not the
forming member ruptures, it is desireable to not allow the forming
member to rupture so as to preserve the viability of its intended
functions described above.
[0059] Over the time that such bulk material container systems have
been in the marketplace, certain design parameters have been
developed for the container systems that provide safe and
successful performance assurance. One such parameter consideration
related to bulk material containment systems that have forming
members with fixedly glued connecting ends (as in FIGS. 2-4), is
that the tolerance difference between the outer circumference
dimension of the forming member and the inner circumferential
surface of the tubular sleeve that operatively engages the forming
member, must not exceed (+/-) 0.25 inches. The relative 0.25 inch
tolerance value at least applies to a forming member of the type
described above which has a forming member outer circumference of
144 inches. It will be appreciated that the 0.25 inch acceptable
tolerance value represents a very small percentage (about 0.17
percent) of the overall nominal circumferential length dimension of
144 inches. Even if the similar tolerance of 0.25 inches is used
for smaller containers such as those having an outer forming member
circumference of 80 inches, the 0.25 inch allowable tolerance value
still only represents about 0.31 percent of the overall nominal
circumferential length parameter.
[0060] The bulk container assembly process for containers of the
type described has generally not been automated in the industry,
but has been manually performed in a time consuming manner,
particularly in view of the need for the outer sleeve member to
snugly engage the outer walls of the forming member. As discussed
in the Background Section above, in order to satisfy the acceptable
snug fit tolerance of 0.25 inches, the container assembler was
required to manually pre-sort both the forming members and the
outer sleeves according to their individually measured actual outer
and inner circumference dimensions respectively, and then match
forming members and sleeves according to their presorted
measurements. It has traditionally been found that for end-glued
corrugated forming members, outer circumference tolerances can be
controlled within a nominal dimension (+/-) 0.25 inch tolerance
variation. However, it has been much more difficult to so
accurately control the inner circumference dimensions of the sleeve
within acceptable snug fit tolerances due to the nature of the
woven polypropylene material from which the outer sleeves are
formed. Even if an outer sleeve is woven to the same nominal
dimension of the forming member plus a 0.25 inch plus tolerance,
applying such sleeve over a forming member having a nominal
dimension with a minus 0.25 tolerance would provide a mismatch
between the forming member and sleeve circumferential dimensions of
0.5 inches, which is outside the permissible snug-fit requirement.
The present invention addresses the costly labor functions of
presorting and matching forming members and outer sleeves prior to
assembly by providing a sleeve that is always manufactured to a
single standardized nominal inner circumference dimension that
matches the nominal outer circumference dimension of the forming
member with which it will be used. As long as the glued forming
member outer circumference dimensions are always within the nominal
(+/-) 0.25 inch tolerance limits, no sorting will be required since
the snug-fit tolerance between a nominally sized circumferential
dimensioned sleeve will always satisfy the (+/-) 0.25 inch
tolerance requirement.
[0061] For example, if the forming member outer circumference
dimension measures at a nominal dimension minus 0.25 inches, the
tolerance difference between a nominally dimensioned sleeve and the
forming member is only minus 0.25 inches, which is within the
snug-fit tolerance limit. In such case, the forming member would
have to be able to stretch 0.25 inches across the entire forming
member sidewall outer circumference before the overlying sleeve
could fully accept the bulk material forces being exerted through
the forming member. However, in such case, tests have shown that
the forming member will generally not rupture under such small
expansion over a larger outer circumferential dimension for the
sidewall. On the other hand, if the forming member outer
circumference is at the nominal dimension plus 0.25 inches, it will
be within the plus 0.25 inch tolerance dimension when matched with
a nominally dimensioned outer sleeve member, but will be 0.25
inches larger in circumference than the inner circumference of the
outer sleeve. This situation, however, is also not a problem since
when applying a sleeve to a forming member, the forming member is
typically slightly mechanically bent or curved when initially
inserting it within the sleeve and can be fully operatively
inserted within the sleeve in a slightly but insignificantly bent
configuration. Once assembled over the forming member, the sleeve
will immediately fully accept any bulk material generated radial
forces transmitted to it through the forming member.
[0062] To achieve the goal of eliminating pre-sorting and matching
of sleeves and forming members during assembly of the container,
one solution is to provide a method of manufacturing an outer
sleeve that always has an internal circumference exactly or very
close to the nominal dimension of the forming member. One technique
for providing such an accurately dimensioned outer sleeve can be
accomplished by initially weaving the sleeve with an inside
circumference dimension that is equal to the determined standard
nominal dimension of the forming member, plus an additional
"circumferential adjustment length" preferably in the range of
about 1.5 inches. When the sleeve is longitudinally extended and
laid in a flat configuration with engaged opposed sides, as it
would appear just before it is initially slid into overlying
engagement with the forming member, the additional "folded over
adjustment length" measurement length would be about 0.75 inches.
Such additional folded over adjustment length material
longitudinally disposed along one side of the sleeve, as shown in
FIGS. 9A and 9B, is referred to herein as a "tail" or "adjustment
tail" 50 of the sleeve material that is used to adjust the
oversized inner circumference dimension of the sleeve down to the
desired standard nominal dimension. It should be noted that the
"adjustment length" measurements are taken in the lateral, or
closed side to closed side direction across the sleeve as opposed
to the longitudinal direction measurement between the opposed open
ends of the sleeve. It is also noted that the term "nominal" as
used with respect to the discussion of dimensions, is that
circumferential dimension of the outer surface of the fixedly glued
end-to-end forming member, or of the inner circumferential surface
of the overlying sleeve, with no tolerance adjustments. While the
length of sleeve material forming the adjustment tail 50 can vary,
it is desirable to have a circumferential adjustment length that is
sufficiently short so that the folded over tail material (generally
indicated at 51 in FIG. 9B) is sufficiently small so as not to
interfere with manufacturing or printing operations related to
producing the sleeve, or to its aesthetic appearance, but is large
enough to provide for accurate stitching of the tail and for
subsequent manual or automated grasping of the sleeve (as
hereinafter described) during assembly of the sleeve 26 to the
forming member/locking assembly. It will also be appreciated that
the sleeve illustrations of FIGS. 9 and 10 are only diagrammatic
and are not to scale. For example, for the sleeve and tail
dimensions for the above described container embodiment, the tail
dimension would be nearly 100 times smaller than the width of the
folded-over sleeve as shown in FIGS. 9 and 10.
[0063] The process of circular weaving of a tubular open-ended
sleeve using polypropylene materials is well known in the art and
is practiced by such companies as Conitex, Sunoco. The outer woven
sleeve surfaces can be coated or laminated during manufacture with
a layer of polypropylene film that can be applied with heat rollers
that impregnate or fuse the polypropylene film material into the
woven fabric in manner known in the weaving art, to add strength
and waterproofing to the woven sleeve material. Following the
initial weaving of the continuous, seamless tubular sleeve, the
elongate tubular sleeve material is advanced along an assembly line
manufacturing process with aid of a series of rollers where various
operations such as the polypropylene coating operation can be
performed on the sleeve material as it passes through the various
functional assembly stages. For example, printing and/or graphics
can be applied to the woven sleeve material as it proceeds down the
assembly line following the weaving and optional coating processes.
Such printing is typically performed by print rollers that engage
and roll along both the upper and lower surfaces of the tubular
sleeve material. Those skilled in the art will recognize the
practices and methods and technology employed in sleeve
manufacturing that enables accurate positioning and alignment of
printing and graphics on the sleeve outer surfaces that will
dimensionally align and mate with the forming member sidewalls that
the sleeve will operatively engage. Those skilled in the art will
also recognize the practices, methods and technology employed to
position, align and form slits or other occlusion formations formed
through the sleeve material at accurately positioned locations
along the sleeve material as, for example, the slits along the
bottom edge of the sleeve illustrated in FIG. 5 that are configured
to cooperatively intersect and engage portions of the locking
member assembly with which they will be functionally connected
during the container assembly process. Such slits or occlusions can
be, for example, performed by a mechanical knife blade or by hot
blade or wire techniques that cut through the woven material in a
manner that prevents the woven material from unraveling adjacent
the cut or slit. These and other known operations may be performed
on the sleeve material prior to or after final sizing of the
interior circumferential dimension of the sleeve.
[0064] The sleeve is accurately sized to a desired universal and
standard nominal internal circumferential dimension by accurately
aligning the "tail" portion of the moving tubular sleeve material
with a stitching or bonding mechanism that reduces the originally
oversized inner circumference of the tubular sleeve down to the
desired nominal dimension preferably along its entire length. The
preferred method of bonding the two overlying layers of sleeve
material in the "adjustment tail" strip of material is by a
stitching process with heavy duty stitching techniques and thread,
of a type commonly used, for example, in the stitching of handles
or seams of FIBC's, as well as is well known in the art. The
stitching head performing the stitching function can be accurately
positioned overlying the strip of adjustment tail material and
synchronized with movement of the sleeve as it proceeds along the
manufacturing assembly line, so that the line doesn't have to stop
to perform the stitching function. Using a typical stitch width of
0.25 inches within a folded over sleeve tail adjustment length of
0.75 inches, the stitching will leave a remaining loop of
unstitched tail material of approximately 0.5 inches along the
longitudinal outside portion of the sleeve, as generally shown in
FIG. 9. Such small extra loop of tail material does not adversely
interfere with either the operation or aesthetic features of the
sleeve. If multiple lateral stitches are used to form the stitch
line bond of the two layers of sleeve material, the radially
innermost positioned stitch line determines the nominal inner
circumference dimension of the sleeve. This dimension can be very
accurately controlled by the relative positioning of the moving
sleeve and the stitching head as the stitching is performed on the
advancing flattened sleeve material. It has been found that the
presence of stitching along one longitudinal edge of the sleeve
does not compromise or weaken the structural strength of the sleeve
or its ability to function in its intended manner in a bulk
container system of the type herein described. Further, unlike
stitching operations used for making FIBC's (bulk bags), since the
stitching is being done on a continuously woven sleeve material,
even if the stitching were to fail, the strength of the continuous
sleeve material would not be diminished, enabling the sleeve to
continue to operate in its intended manner to contain the bulk
material within the container.
[0065] The universal nominally sized sleeve material can be shipped
in continuous rolled configuration as manufactured, to the entity
that applies the sleeve to the forming member/locking assembly. The
receiving entity would then need to separate successive individual
sleeves as they are applied to a forming member by cutting them to
a proper length either before or directly after sliding the sleeve
in operative position over the forming member/locking assembly.
[0066] Alternatively, oversized sleeve material that has not yet
been sized to the nominal inner circumference dimension can be
shipped in roll or individually cut and bundled form to a location
remote from the point of weaving of the sleeve, where the final
sleeve sizing operation will be performed. Such remote location
might typically be at the point of manufacture of the forming
member/locking assembly or where the sleeve is operatively applied
in overlying manner to the forming member/locking assembly. At such
facility, the sleeve could be individually bonded/stitched or
continuously bonded/stitched as unwound from a sleeve roll to
provide a desired nominal inner circumference dimension by forming
an adjustment tail 50 as described above. If performed at a
location where the sleeve is operatively applied to the forming
member/locking assembly, the bonding/stitching operation could even
be automated to match the outer circumferential dimension of each
glued forming member by, for example, first measuring the actual
outer circumference of each forming member on the assembly line, by
adjusting the position of the bonding equipment relative to the
adjustment tail portion of the sleeve to provide an inner sleeve
circumference that matches the measured circumference and by then
forming a bonded adjustment tail 50 such that the inner
circumference of the sized sleeve matches the actual outer
circumference of the glued forming member to which it will be
applied. Those skilled in the art will recognize yet other
manufacturing and container assembly scenarios applicable to
practicing the present invention.
[0067] The sleeve could also be sized to the desired universal
nominal dimension by initially oversizing the inner circumference
of the woven sleeve to provide a plurality of adjustment tail
lengths, such as, for example, an adjustment tail length on
oppositely spaced sides of the sleeve as it proceeds down the
assembly line. Using this technique, the stitching or other forms
of bonding as discussed above and below would be performed on both
of the spaced adjustment tail length sections to produce a sleeve
with two oppositely disposed tails, as diagrammatically pictorially
shown in FIGS. 10A and 10B. FIG. 10B illustrates an enlarged
fragmentary view of the upper end portion of the outer sleeve
configuration of FIG. 10A. In this case, the stitching or bonding
equipment would be accurately positioned relative to each other
across the sleeve such that the nominal inner circumferential
dimension of the sleeve is established by that bonded sleeve
material that is positioned between the innermost stitches or
innermost spaced stitched bonds 52a, 52b formed by the spaced
stitching or bonding equipment. This technique would yield a
completed sleeve configuration having two separate tail loops 50a,
50b of material longitudinally extending along opposed sides of the
sleeve 26. Preferably, the circumferential adjustment sleeve length
measurements and thus the folded over adjustment sleeve length
measurements 51a, 51b of the tail loops 50a, 50b would be about the
same, but would not necessarily have to be the same, as long as the
desired final inner circumferential dimension of the sleeve is
accurately attained.
[0068] Besides accurately defining a desired inner circumference
sleeve dimension the external adjustment tail material can be used
to facilitate manual or automated process for operatively
assembling the sleeve 26 to the forming member 22/locking assembly
24. Previously, the sleeve to forming member assembly process has
generally been manually performed, typically by two assembly
workers, one on each side of the folded-in-half forming member. The
assemblers would grasp and slightly "open" one end of the sleeve
from laterally opposed positions, would slide the opened sleeve end
over one end of the folded-in-half forming member, and then pull
the sleeve longitudinally along the length of the forming member to
its desired position, as previously discussed. To facilitate the
sliding assembly process, the forming member is typically slightly
bent in arcuate manner between its lateral sides during the process
to minimize catching of the sleeve on the leading edge of the
forming member. Further, as shown in FIGS. 3 and 4 the outer upper
leading corners of the forming member 22 are slightly curved at
34b, to minimize catching of the corners on the sleeve during the
sliding operation. The externally projecting sleeve tail 50
portions provide a mechanism for facilitating and decreasing the
assembly time of applying the sleeve 26 to the forming member 22.
This is particularly true for the double tail 50 embodiment of the
sleeve shown in FIG. 10. The opposed external tail portions 50a,
50b provide ready handles for assemblers to grasp while inserting
and pulling the sleeve 26 over the forming member 22. In an
automated assembly process the sleeve tail portions 50a, 50b can
readily be grabbed and moved by, for example, a 2-finger gripper of
the type attachable to a robotic arm of a universal robot. Such
automated robotic equipment is well known by those skilled in the
art and is available, for example, from the Gross Company, Robotiq
and others. Complete electromechanical, pneumatic and robotic
motion control solutions are available in the industry and readily
customizable for automating the sleeve sizing and assembly process
to minimize or eliminate costly manual labor functions.
[0069] Although stitching is the preferred technique for bonding
the overlying sleeve layers in the adjustment tail region 50, other
bonding techniques could be used, such as fusing a seam with a hot
wheel/bar method, or by ultrasonic welding techniques, both
well-known in the art. In ultrasonic welding of thermoplastic
materials such as that of the woven polypropylene sleeve material,
the weld technology uses mechanical vibrations to generate heat due
to molecular friction. As the molecules are energized, the plastic
material becomes soft and starts melting and forms a bond between
the two engaged sleeve layers which are bonded together by cohesion
for form-fit joints. After a short hold time under pressure, the
layers are molecularly firmly joined. Because of its high process
speed, ultrasonic joining/welding technology is readily adaptable
to bonding of the sleeve tail material as the sleeve moves along on
the manufacturing assembly line. Herrmann Ultrasonics, Inc. is a
well-known leading company in the field of ultrasonic welding and
has a wide array of equipment and machines and product lines that
provide numerous variances that can be tailored by those skilled in
the art to specific specifications for bonding the sleeve
adjustment tail material as discussed above. Whether the sleeve
material is formed to its uniform desired uniform nominal inner
circumferential dimension by stitching, by a hot wheel-bar method,
or by ultrasonic welding, the sleeve produced has an accurate known
nominal dimension that can be directly applied to the glued forming
member having a nominal (+/-) 0.25 inches without requiring any
presorting and matching of forming members and sleeves in the bulk
material container assembly process.
[0070] This specification provides several examples of embodiments
of bulk material container configurations and assembly methods
incorporating the principles of this invention. Other embodiments
of the invention can be made without departing from the spirit and
scope of the invention, which resides in the claims hereinafter
appended.
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