[0001] The present invention relates to a multi-layered flat walled bulk storage bin or
container made from collapsible or compressible sheet material such as corrugated
board. More particularly, the invention relates to a container formed by winding compressible
sheet layers to form a sleeve having flat sides with corners between adjacent sides
crushing the corners and having at least two opposite corners bevelled to allow the
sleeve to be easily collapsed for storing when not in use.
[0002] The conventional manner of making multi-layered containers was to glue several corrugated
layers together, score a fold line in the appropriate places and then fold the layers
to form a sleeve. This method formed a container with a butt joint, where the two
ends butt together or a lap joint where the two ends overlap.
[0003] Corrugated board containers may also be made by winding corrugated layers about a
mandrel with flat sides and glueing each layer to the adjacent layer to form a sleeve.
Containers made by this method have no butt or lap joints and therefore use less material
than more conventional containers or bulk bins having the same strength properties.
[0004] An example of making a container or bulk bin by winding layers about a mandrel is
disclosed in our co-pending U.S. Patent Application 397,990 filed July 14, 1982. In
this method, layers are convolutely wound about a mandrel, the corners of each layer
are compressed on the mandrel as the container is wound which results in a container
that can be more easily folded for storage purposes after it has been made.
[0005] The most obvious corner profile for a container is a right angle, which provides
maximum concentration of pressure during the crushing step, thus giving the most efficient
means of crushing. However, it has been found that the right angle corner would not
fold flat when the corner was folded to the fully closed position and had a spring
back which required a counter force to flatten it. It has now been found that a multi-layered
sleeve can be made by providing bevels on opposing corners of the sleeve and compressing
the layers at these bevelled corners. These crushed bevelled corners avoid the spring
back that sometime occurs when the finished sleeves are flattened for storage purposes.
[0006] The flattened sleeves provide a distinct advantage for conveying, printing and other
processes that are applied to the sleeves after forming.
[0007] This foldability is a labour saving feature allowing container sleeves to be folded
easily by one person without applying force.
[0008] The present invention provides a container comprising a multi-layered sleeve having
at least four flat sides with corners between adjacent sides, the sleeve having compressible
sheet layers with crushed corners and at least two opposing corners being bevelled
corners to allow the sleeve to be collapsed, so fully closed corners have adjacent
sides substantially parallel without additional force applied.
[0009] The present invention also provides in one embodiment, for the bevelled corners to
have an inside bevel width (y), substantially proportional to caliper (x) of the container,
where the caliper represents the thickness of the container. In a preferred embodiment,
the width (y) is determined according to the formula y=0.0294 + 0.347x, and the width
is to the nearest eighth inch.
[0010] In other embodiments of the invention, four flat sides are provided with two opposing
corners being bevelled corners and the bevels are in the range of about 1/4 to 3/4
of an inch wide. The container is preferably made from a flat sheet liner on the inside
and multiple layers of single face corrugated sheet wound on the liner. In other embodiments,
all the corners of the container are bevelled and caps are provided to fit over the
top and the bottom of the sleeve.
[0011] The bevelled corners in a preferred embodiment have a flat inside bevelled surface,
at an angle of in the range of about 30° to 60°, preferably 45°. In other embodiments,
the inside bevelled surface may be multi-faceted or curved.
[0012] In drawings which illustrate embodiments of the invention and accompany this specification,
Fig. 1 is an isometric view of a multi-layered container according to one embodiment
of the present invention,
Fig. 2 is a top plan view of the container shown in Fig. 1,
Figs. 3, 4 and 5 are detailed plan views showing a right angled corner known in the
prior art of a four layered container in the right angled position and fully opened
and fully closed folded positions,
Figs. 6, 7 and 8 are detailed plan views showing a preferred bevelled corner of a
four layered container in the right angled position and fully opened and fully closed
folded positions,
Figs. 9, 10 and 11 are detailed plan views showing a bevelled corner of a four layered
container having a wide bevel width, in the right angled position and fully open and
fully closed folded positions,
Figs. 12, 13 and 14 are detailed plan views showing a preferred bevelled corner of
a seven layered container in the right angled position and fully opened and fully
closed folded positions,
Fig. 15 is a graph showing the preferred relationship between the inside bevel width
(y) and the container caliper (x),
Figs. 16, 17, 18 and 19 are detailed plan views showing different types of bevels.
[0013] An example of a container 10 or bulk bin is shown in Fig. 1 having three layers 11
of single face corrugated sheet wrapped around a flat sheet liner 12. Whereas a single
face corrugated sheet is illustrated in this embodiment, a foam backed paper would
also be applicable depending on the requirements of the container 10. Two bevelled
corners 13 oppose each other on the container 10 and have crushed layers at each bevelled
corner 13. The other two opposing corners 14 are not bevelled but are crushed so that
the container can be folded and lie flat.
[0014] The thickness of the sides of the container is referred to as the "Caliper", sometimes
as the Board Caliper. Although two bevelled corners 13, provided they are opposite,
allow easy folding of the container, it is preferred to bevel all four corners because
then it does not matter which corners are fully folded, the container folds flat about
all corners.
[0015] A bottom cap 15 is shown at the bottom of the container 10 which exactly fits around
the sleeve in the open position. The cap 15 is made in a conventional manner, generally
of not more than two corrugated layers. A top cap (not shown) may be provided to close
the container if required. The top cap may be identical in construction to the bottom
cap 15.
[0016] Fig. 2 shows a four layered container 10 having four sides and having four bevelled
corners 13. Each of the bevelled corners 13 is compressed across the bevel so that
the container 10 may be collapsed with either of the pairs of opposing corners opening
out to the open or fully closed folded position. Whereas both examples in Figs. 1
and 2 illustrate containers having four sides, it will be understood that a container
may be made with more than four sides.
[0017] A six or eight sided container may be made with at least two opposite corners being
bevelled corners so that the container could be collapsed with the bevelled corners
forming the fully closed folded position.
[0018] Figs. 3, 4 and 5 illustrate a right angle corner as is known in the prior art. Four
layers 11 of single face corrugated sheet layers are formed about a flat sheet liner
12 and glued to each other to form a container. The corners 14 shown right angled
in Fig. 3 are compressed. As can be seen in Fig. 4, when the container is folded flat,
the corner 14 opens out to the open position to allow the three layers to bend about
the flat sheet liner 12 without causing any delamination of the glued layers or between
the first layer 11 and the liner l2.
[0019] Fig. 5 illustrates a fully closed folded position of the corner 14, and as can be
seen, the corner does not fully fold so the inside flat sheet liner 12 is tapered.
To make the two inner surfaces parallel, it is necessary to apply pressure to overcome
the spring back force. The inability of the corner to fully fold may result from the
liner 12 being pinched together at the corner 14. Forming this type of corner completely
closed can result in severe damage and loss of structural integrity to the corner
and hence to the container.
[0020] Figs. 6, 7 and 8 illustrate a four layered container with a bevelled corner 13 having
a preferred inside bevel width (y), as shown in Fig. 6 in the right angled position.
As can be seen, the crushing of the layers 11 extends the crushed portion to not just
the bevel but right across the face of the bevel'so that there is a predominately
flat bevelled surface at the corner of the container. When the container is folded
flat with the bevelled corner fully opened to the opened position, as shown in Fig.
7, the bevel does not appear. However, when the corner is fully closed as can be seen
in Fig. 8, the bevelprovides a triangular space 16 which allows the two inner surfaces
of the liner 12 to remain substantially flat and parallel to each other. This is the
preferred embodiment of the corner and requires no force.on the container to fold
flat.
[0021] Figs. 9, 10 and 11 illustrate another example of a bevel, where the inner bevel width
is too wide for the caliper of the container. The right angled position shown in Fig.
9 and the fully open position shown in Fig. 10 are satisfactory, but when the corner
is in the fully closed position as shown in Fig. ll, the inside surfaces of the liner
12 do not lie flat and parallel to each other, but are tapered in the reverse direction
to that shown in Fig. 5 which has no bevel or too small a bevel. This configuration
is acceptable for folding as no spring back occurs, and the container lies flat, however
it takes up more space, and the space is wasted when the containers are laid flat
one upon the other.
[0022] Figs. 12, 13 and 14 illustrate a seven layered container having a preferred inside
bevel width (y) as shown in Fig. 12 in the right angled position. Fig. 14 illustrates
clearly that the inside surfaces of the liner 12 lie flat and substantially parallel
when the corner is in the fully closed position.
[0023] To determine the relationship between caliper (x) and inside bevel width (y), a number
of tests were carried out on different board calipers for three ply up to ten ply
and for different types of corrugated board and it was found that the overall caliper
(x) was the key factor, not the different types of ply. The bevel should preferably
be flat when the corner was in the fully opened position, and form a triangular space
16 when.in the fully closed position. Fig. 15 shows that the relationship between
inside bevel width (y) and caliper (x) follows a straight line, and the relationship
was according to the formula: y=0.0294 + 0.347x.
[0024] It is preferable for ease of manufacture to make the inside width of the bevel to
a certain series of fixed increments so that standard mandrels can be used. In one
embodiment, the inside bevel widths were made to 1/4", 3/8", 1/2", 5/8", 3/4". Figures
6, -7 and 8 illustrate - a 1/4" bevel for a container having a caliper of 0.60".
[0025] The shape of the bevels are preferably flat on the inside and at an angle of 45°
for symmetry as shown in Fig. 16. However a range of angles, from 30° to 60° can be
used as shown in Fig. 17. Furthermore a multi-faceted bevel as shown in Fig. 18 may
be used or a curved bevel as shown in Fig. 19. The width of bevel (y) is measured
between the points on the adjacent inside faces where a change occurs from the flat
surface. The shape of the bevel is arranged so that the inside of the bevel lies flat
when the corner is in the fully open position.
[0026] The width of the bevel depends partly on the shape and size of the container and
the size and the number of layers. It has been found that up to at least six layers
can be formed into a container and the preferred bevel is in the order of 1/4 inch
although bevels of up to 3/4 of an inch may be applicable in certain cases. The measurements
represent the inside face width of the bevel. The bevelled corner gives the correct
corner geometry necessary to result in corner creases which are easy to fold.
[0027] The unique corner requires less labour and less force to fold the box and results
in less spring back from a folded sleeve. Furthermore, the sleeve'has superior strength
due to structural integrity because the corners are not damaged by folding. When a
sleeve is wound on a mandrel, the container has no butt joints or cap joints, therefore
there are no areas or weaknesses as in corrugated containers made by conventional
methods having butt or lap joints. The sleeve may be trimmed by a sawcut at both edges
thus providing a perfectly square sleeve for fitting into a cap 15 as shown in Figure
1. The layered container also provides a superior panel rigidity and thus better resists
bulging.
[0028] The bevelled corners can be utilized with containers made by crushing the corners
after the container has been formed, known as "post" crushing or in the case where
layers are wound about a mandrel, each layer is crushed as it is wound in accordance
with co-pending U.S. Patent Application 397,990 known as "continuous" crushing.
[0029] Various changes may be made without departing from the scope of the present invention
which is limited only by the following claims.
1. A container (10) comprising a multi-layered sleeve having at least four flat sides
with corners (13) between adjacent sides, the sleeve having compressible sheet layers
(11) with crushed corners, characterized in that at least two opposing corners (13)
are bevelled corners to allow the sleeve to be collapsed so that fully closed folded
corners have adjacent sides substantially parallel without additional force applied.
2. A container according to claim 1, characterized in that the bevelled corners (13)
have an inside bevel width (y) substantially proportional to caliper (x) of the container.
3. A container according to claim 2, characterised in that the width (y) is determined
according to the formula y=0.0294 + 0.347x.
4. A container according to claim 2 or claim 3, characterized in that the width (y)
is selected from one eighth inch increments.
5. A container according to any one of claims 1-4, characterized in that the bevelled
corners (13) are in the range of about % to % of an inch.
6. A container according to any one of claims 1-5, characterized by a flat sheet liner
(12) on the inside of the sleeve and multiple layers (11) of single face corrugated
sheet wound on the liner.
7. A container according to any one of claims 1-6, characterized in that the container
has four flat sides with all corners (13) being bevelled corners.
8. A container according to any one of claims 1-7, characterized by caps (15) which
fit over the top and bottom of the sleeve.
9. A container according to any one of claims 1-8, characterized in that the bevelled
corners (13) have a flat inside bevel surface.
10. A container according to claim 10, characterized in that the bevelled corners
have a flat inside bevel surface at an angle in the range of about 30 to 60°, preferably
about 45°.
11. A container according to any one of claims 1-8, characterized in that the bevelled
corners (13) have a multi-faceted inside bevel surface.
12. A container according to any one of claims 1-8, characterized in that the bevelled
corners have a curved inside bevel surface.