[0001] The present invention relates to a closure for closing an opening of a container.
In particular, it relates to a closure device which is screwed onto a drinks container.
[0002] It is known to package potable fluids such as water in a container having a detachable
closure to seal the container. The container and closure are typically moulded. A
thread or groove is formed on the bottle, around the opening, and a complimentary
thread or groove is formed on the inside of the closure. If there are any inaccuracies
in the moulding of the thread and groove, then the cap may not form a fluid tight
seal over the opening. This may result in a leakage of fluid from the container.
[0003] US 2004/188375 discloses a cap and container wherein the cap comprises an annular skirt portion
and a top wall; the top wall comprising rigid sealing members for engaging a lip of
a container opening. A closure comprising the technical features of the preamble of
claim 1 is known from
US 3281000.
[0004] The present invention provides a closure as set out in claim 1.
[0005] The present invention provides a container combined with a closure as set out in
claim 7.
[0006] This has the advantage that a fluid tight seal is formed between the closure and
the container, even if there are inaccuracies in the moulding of the closure or container.
[0007] Optional features of the invention are set out in the dependent claims.
[0008] Preferably, the neck comprises a radiussed surface for engagement with the second
sealing surface. Thus, the surface area of the neck in contact with the sealing surface
is increased.
[0009] Preferably, the or each sealing surface is annular. Thus, a uniform sealing surface
is provided which can be readily engaged with the container.
[0010] Preferably, the attachment means comprises one or more helical threads and grooves.
Thus, a secure and releasable engagement means is provided.
[0011] Preferably, the or each projection comprises a cavity. Thus, the projection is readily
deformable when urged against the neck of the container, to ensure that a good seal
is formed even if there are inaccuracies in the moulding.
[0012] Preferably, the neck comprises one or more cavity or cavities. Thus, the neck is
readily deformable when urged against the sealing surface of the closure, to ensure
that a good seal is formed even if there are inaccuracies in the moulding.
[0013] Preferably, the closure comprises a stop to limit movement of the neck relative to
the closure. Thus, the projection or neck is not deformed so much that plastic deformation
or breakage occurs.
[0014] Preferably, the closure is integrally moulded. Thus, the closure can be cheaply manufactured.
[0015] In a further aspect, the present invention provides a closure for closing an opening
of a container, wherein at least a part of the closure is formed from a thermoplastic
polymeric material comprising polylactic acid (PLA) (also known as poly(lactide))
or a derivative thereof, and wherein the thermoplastic polymeric material is amorphous
or at least partially amorphous.
[0016] In a still further aspect, the present invention provides a closure for closing an
opening of a container, the closure comprising: a thread or groove engageable with
a corresponding portion of a container to provide closure of the container, wherein
the closure is sized to interact with the container such that the closure is deformable
on engagement with the container, such that engagement of the closure relative to
the container can flatten a curved external surface of the closure such that at least
one flattened surface is formed on the external surface of the closure.
[0017] In a yet further aspect, the present invention provides a closure for closing an
opening of a container, the closure comprising: a thread or groove engageable with
a corresponding portion of a container to provide closure of the container, wherein
the closure has at least one flattened surface formed on an external surface of a
side wall of the container; wherein the side wall is formed of a material of substantially
uniform thickness.
[0018] Embodiments of the present invention will now be described, by way of example only,
with reference to the accompanying drawings in which:
Figure 1 is a cross-sectional view of a closure and container;
Figure 2 is a cross-sectional view of a second version of the closure and container;
Figure 3a is a cross sectional view of a third version of the closure and container;
Figure 3b is a cross sectional view of a fourth version of the closure and container;
Figure 4 is a cross sectional view of a fifth version of the closure and container;
Figure 5 is a cross sectional view of a sixth version of the closure and container;
Figure 6 is a cross sectional view of a seventh version of the closure and container;
Figure 7 is a cross sectional view of an embodiment of the closure and container in
accordance with the present invention;
Figure 8 is a cross sectional view of an embodiment of the closure in accordance with
the present invention;
Figure 9 is a plan view of a closure;
Figure 10 is a plan view of a closure engaged with container;
Figure 11 is a cross-section through the closure of Figure 10 along a line A-A; and
Figure 12 is a cross-section through the closure of Figure 10 along a line B-B;
Figure 13A is a schematic partially cut-away cross-section of a further embodiment
of the closure;
Figure 13B is a schematic cross-section of an alternate part of the closure of Figure
13A.
[0019] Referring to Figure 1 there is shown a container 22 having a neck 20. The remainder
of the container 22 is not shown as its body shape may take any suitable form and
may, for example, be of square, rectangular or circular cross-section, or another
geometrical shape.
[0020] The neck 20 defines a circular opening 28 having a central axis and surrounded by
a substantially smooth, cylindrical internal surface 30. An internal edge 24 is formed
at an end of the internal surface 30 remote from the body of the container 22. An
external surface 32 of the neck 20 has an external edge 26 at an end remote from the
body of the-container 22, the external edge 26 being radially outside the internal
edge 24.
[0021] The external surface 32 is provided with attachment means with which to engage complementary
attachment means provided on a closure. The attachment means may take the form of
a helical thread or groove 34. The thread or groove 34 may be a single thread or groove,
or alternatively be in the form of a plurality of threads or grooves having different
starting points.
[0022] The closure 2 is also shown in Figure 1. The closure 1 has a top 4 which is circular
in plan view, and merges at a radially outer edge with a depending annular side wall
6. The side wall 6 is provided, on its inner surface, with attachment means for releasable
engagement with the complementary attachment means provided on the neck 20. The attachment
means may take the form of one or more helical threads or grooves 8. The side wall
6 defines a central axis, extending longitudinally along an axis of symmetry of the
closure. The central axis is marked as line A-A on Figure 1.
[0023] The closure 2 is provided with an annular projection 10 extending from the top 4,
the projection 10 extending from the same side of the top 4 as the side wall 6. The
projection 10 is provided with an angled, or sealing, surface 12, which faces radially
outwardly and away from the top 4. The angled surface 12 is preferably angled at 45
degrees to the top 4, and may be angled between 10 and 80 degrees. The angled surface
12 can be considered to be inclined to a plane perpendicular to the central axis of
the closure. The angled surface 12 could also be considered to be inclined to the
longitudinal axis of the threads or grooves 8 of the closure.
[0024] The annular projection 10 is circumferentially spaced apart from the side walls 6.
The angled surface 12 is located such that when the closure 2 is attached to the container
22 by the attachment means, the internal edge 24 of the neck 20 abuts against the
angled surface 12 in order to close the opening 28.
[0025] The angled surface 12 is shown in profile to define a straight line. The angled surface
may also have an arcuate profile. The effect of the angle is that the angled surface
12 and/or the neck 20 undergo a slight elastic deformation in a radial direction when
urged together.
[0026] Figure 2 shows a second version of the neck 20. The internal surface 30 has an internal
radiussed surface 224 at an end remote from the body of the container 22. The closure
2 and the other features of the container 22 are as described in the first version.
[0027] The internal radiussed surface 224 has a profile curved with a constant radius, or
the surface 224 may take any arcuate form. The angled surface 12 may also have an
arcuate profile, which may be complementary to radiussed surface 224. The radiussed
surface 224 and angled surface 12 may abut each other to seal the opening 28. The
internal surface 224 may alternatively be chamfered at an angle complimentary to the
angle of the angled surface 12, as shown in Figure 2. The radiussed surface 224 provides
a greater surface area in contact with the angled surface 12 than provided by the
edge 24.
[0028] Figure 3a shows a further version of the closure 2. The closure 2 is provided with
a second projection 310. The second projection 310 is an annular projection extending
from the top 4 in substantially the same direction as the annular projection 10 and
side walls 6. The second projection 310 is located radially outwardly and spaced apart
from the projection 10. The second projection 310 is provided with a second angled
surface 312. The second angled surface 312 faces radially inwardly, and away from
the top 4. The angled surface 312 is shown in profile to define a straight line. The
angled surface 312 may also have an arcuate profile.
[0029] The second angled surface 312 is positioned to abut external edge 26 of the neck
20, in order to assist in the sealing of opening 28.
[0030] The second projection 310 may be the same size, or larger or smaller than the projection
10. The angled surface 312 may be orientated at the same angle from the top 4 as the
projection 10, or alternatively, the second angled surface may be at a smaller or
larger angle than the angled surface 12.
[0031] Figure 3a shows annular projection 10 in abutment with the internal radiussed surface
224 of the second version. Alternatively, the internal surface 30 may end at an internal
edge, for example internal edge 24 as described in the first embodiment.
[0032] Figure 3b indicates that external surface 32 of the neck 20 has an external radiussed
surface 326 at an end remote from the body of the container 22. The external radiussed
surface 326 may have a profile curved with a constant radius, or the surface 326 may
have a profile of any arcuate form. The surface 326 may also have an arcuate profile,
which may be complementary to radiussed surface 312. The radiussed surface 326 and
angled surface 310 may abut each other to assist in sealing the opening 28.
[0033] The radiussed surface 326 may alternatively be chamfered at an angle complimentary
to the angle of the angled surface 312, as shown in Figure 3b. The radiussed surface
326 provides a greater surface area in contact with the angled surface 310 than provided
by the edge 26. The abutment of the external radiussed surface 326 with the second
angled surface 312 assists in sealing the opening 28.
[0034] Figure 4 shows a version with differences from the second version described above
and shown in Figure 2. An annular projection 410 is provided on the top 4, the annular
projection 410 having an angled surface 412 as previously described. The annular projection
410 is not a solid projection, but comprises a cavity. The annular projection 410
is hollow and defines an annular groove 405 on the top 4. The annular projection 410
may alternatively comprise a cavity which does not have an opening. The hollow projection
410 results in the angled surface 412 being more easily elastically deformable than
the angled surface 12 when urged by the neck 20.
[0035] The angled surface 412 is shown in profile to define a straight line. The angled
surface 412 may also have an arcuate profile, which may be convex or concave.
[0036] The internal surface 30 may have an internal radiussed surface 424 at an end remote
from the body of the container 22. The closure 2 and the other features of the container
22 are as described in the first version.
[0037] The internal radiussed surface 424 may have a profile curved with a constant radius,
or the surface 424 may take any arcuate form. The internal radiussed surface 424 may
take the form of a chamfer, having a profile of a straight line. The internal radiussed
surface 424 may be an edge. The angled surface 412 may have an arcuate profile or
straight-line profile complementary to radiussed surface 224.
[0038] The closure 2 may optionally be provided with a stop 407, the stop 407 being an annular
projection on the top 4 and adjacent the side wall 6. The stop 407 is positioned to
be engageable with the end of the neck 20 remote from the body of the container 22,
when the closure 2 is attached to the neck 20. The stop 407 has a height chosen to
allow some elastic deformation of the angled surface 412, but limits movement of the
neck 20 to prevent excess deformation of the annular projection 410.
[0039] Figure 5 shows a further version of the neck of the container. Neck 520 is provided
with an annular cavity 505 extending around the neck. The cavity 505 opens onto the
end of the neck 20 remote from the body of the container 22, but may alternatively
open onto the internal surface 530 or external surface of the neck. Internal edge
524 of the neck 520 is able to engage with angled surface 512 on the closure 2. When
the internal edge 524 is urged onto the angled surface 512, the part of the neck supporting
the internal edge 524 can elastically deform inwardly, into the cavity 505. This embodiment
thus allows a relatively large elastic deformation of the neck in order to create
a good seal for closing the opening.
[0040] The angled surface 512 and projection 510 may be any of the surfaces or projections
described in any of the embodiments. The internal edge 524 may be a radiussed edge,
or chamfered or arcuate, as described in any of the versions.
[0041] The closure 2 for use with neck 520 may be provided with a stop as described in the
embodiment of Figure 4, in order to limit the deformation of the neck 520.
[0042] The neck may optionally be provided with a second cavity (not shown) adjacent an
external edge of the neck. The second cavity may allow greater elastic deformation
of the neck with a second angled surface in the version of Figures 3a or 3b. Third
and/or further cavities may be provided for the same purpose.
[0043] Figure 6 shows a further version of the closure 2. Neck 620 is the same as that described
in Figure 5, having a cavity 605. Edges 611 are formed at the end of the annular cavity
605 remote from the container.
[0044] Closure 2 is provided with a projection 610, having two angled sealing surfaces 612.
One angled surface 612 faces radially outwardly, and one angled surface 612 faces
radially inwardly. Each angled surface is inclined at an angle of approximately 10
to 80 degrees to the central axis of the closure.
[0045] The projection 612 may be hollow, comprising a cavity to allow it to readily elastically
deform. Alternatively, the projection 612 may be solid.
[0046] The angled surfaces 612 are located to each engage with an edge 611 of the neck 620.
The apex of the projection 610 thus extends into the cavity 605. As the edges 611
are urged against the angled surfaces 612, the edges 611 may be urged radially apart
and/or the sealing surfaces 612 may be urged radially together.
[0047] The edges 611 may be radiussed, or may have an arcuate profile or be chamfered. The
angled surfaces 612 may have a straight-line profile, or have a convex or concave
arcuate profile.
[0048] Closure 2 may comprise more than one projection 610, each projection comprising two
sealing surfaces 612. The neck 620 may comprises a corresponding number of cavities
605 having edges for sealing against surfaces 612. For example, the neck 630 may comprise
three cavities 605, extending parallel to each other and circumferentially spaced.
The three cavities 605 will form a total of six edges 611. The closure 2 would comprise
three projections 610, having a total of six sealing surfaces 612. All the sealing
surfaces 612 would simultaneously engage against the edges 611 to seal the opening
of the container. Furthermore, the or each projection 610 may have one, two or more
sealing surfaces 612.
[0049] The closure 2 may be integrally formed as a single piece, for example by moulding.
Alternatively, the closure 2 may be formed in two or more pieces, for example with
the angled surface formed on an insert which is secured to the inside of the top 4.
[0050] Figure 7 shows an embodiment of the present invention related to the version shown
in Figure 4. A closure 702 comprises an annular projection 710 provided on a top 704.
The annular projection 710 has an angled surface 712 analogous to the earlier described
versions. The angled surface 712 is orientated at approximately 45° to the plane surface
of the top 704. The annular projection 710 and top 704 are integrally formed of a
material having a substantially uniform thickness over the top 704.
[0051] The annular projection 710 defines an annular groove 705 on the top 704. The groove
705 allows the annular projection 710 to be easily elastically deformable when a neck
720 of the container is urged against the angled surface 712.
[0052] The top 704 is shaped to form a stop 707. The stop 707 is an annular projection integrally
formed with the top 704, and adjacent to a side wall 706 of the closure. The stop
707 is positioned to be engageable with the end of the neck 720 remote from the body
of the container, when the closure 702 is attached to the neck 720.
[0053] The stop 707 is arranged so that the neck 720 can contact the angled surface 712,
and when the neck 720 is urged against the angled surface 712 the annular projection
710 can be elastically deformed by the neck 720. The stop 707 is located to limit
movement of the neck 720 relative to the angled surface 712 to prevent excess deformation
of the annular projection 710. The stop 707 also assists in preventing the neck 720
being splayed outwardly by the annular projection 710. The stop 707 may also prevent
the closure 702 from being over-tightened onto the neck 720.
[0054] An internal groove 736 is located between the stop 707 and the angled surface 712.
When the neck 720 is engaged with the stop 707, the annular internal groove 736 allows
improved elastic deformation of the projection 710, allowing the annular projection
710 to undergo a larger deformation for the same force from the edge 724 of the neck
720. The location of the internal groove 736 means that the edge 724 of the neck 720
contacts the annular projection 710 at a line spaced apart from the radially outward
edge of the annular projection 710. The annular projection 710 can be more easily
be deformed when contacted away from a fixed end, that spacing being provided by the
internal groove 736.
[0055] The internal surface edge 724 of the neck 720 may be radiussed or chamfered in a
similar manner to the surface 424 described with reference to Figure 4.
[0056] The top 704 is shaped to provide an annular shoulder 738. The shoulder 738 is located
between the stop 707 and the side wall 706. The shoulder 738 extends from the restraining
surface 744 at an angle to the plane of the top 704. When the neck 720 is engaging
with the closure 702, the shoulder 738 is adjacent to an external surface 732 of the
neck 720. The shoulder 738 is arranged to guide the neck 720 towards the stop 707
as necessary. The restraining surface 744 may alternatively have an angular lead-in
to the stop 707, i.e. at tan angle to the side wall. The lead-in may alternatively
be radiussed adjacent to the stop 707.
[0057] An annular restraining surface 744 extends substantially parallel to the side wall
706. The restraining surface 744 is located between the stop 707 and the shoulder
738, radially outwardly of the sealing surface 712. The restraining surface 744 faces
radially inwardly, substantially facing the sealing surface 712.
[0058] The restraining surface 744 limits the radial movement of the neck 720. The restraining
surface 744 is radially spaced from the external surface 732 of the neck 720 when
the closure 702 is initially being attached to the container. The neck 720 when attached
to the closure 702 preferably deforms the annular projection 710 by a distance in
a radial direction. This deformation distance is preferably greater than the radial
distance between the restraining surface 744 and the external surface 732 of the neck
720. The neck 720 is maintained in contact with the angled surface 712, with the annular
projection 710 deformed, even when the neck 720 splays outwardly. There is preferably
an initial 0.05mm radial clearance between the restraining surface 744 and external
surface 732.
[0059] The restraining surface 744 joins the stop 707 at a corner. The profile of the restraining
surface 744 and stop 77 preferably supports the neck 720. The corner preferably has
a radius of curvature equal to or smaller than the radius of curvature of the corresponding
outer edge of the neck 720 of the container.
[0060] The top 704 is preferably formed of thicker material at its radial periphery 740.
This may increase the strength of the top 704 in this area.
[0061] Alternatively, the top 704 may be formed of material having a substantially uniform
thickness. Such an embodiment is shown with part of the top 704 shown by the dashed
line 760 in Figure 7.
[0062] Figure 8 shows a further embodiment of the present invention of a closure. Top 804
defines an annular projection 810 having an angled surface 812. A groove 805 allows
the annular projection 810 to elastically deform when a neck of a container is urged
against it.
[0063] The top 804 defines a stop 807. The stop 807 is located between the annular projection
810 and the sidewall 806. The stop 807 extends substantially parallel to the top 804.
A groove 805 allows elastic deformation of the projection 810 when a neck engages
the stop 807. An internal groove 836 allows the neck of the container to contact the
annular projection 810 away from the end of the projection 810 connected to the stop
807. This allows the projection 810 to deform more readily when the neck is urged
against the projection 810.
[0064] Figure 9 shows a schematic plan view of an embodiment of the closure 2. The side
walls 6 of the closure 2 in this embodiment are circular in plan view when the closure
2 is not attached to the container.
[0065] The closure 2 is provided with groups of threads or grooves 34 arranged symmetrically
around the side wall 6 of the closure 2. Preferably, there are four groups of threads
or grooves 34. Between each group is a region 46 of the side wall 6 which is not provided
with a thread or groove 34. The threads 34 extend radially inwardly from the side
wall 6 further than the side wall 6 at the regions 46. Each group of threads or grooves
may comprise one, two or more substantially parallel ridges or grooves forming a helical
thread.
[0066] The discrete groups of threads or grooves 34 are separated by smooth regions 46.
The regions 46 may improve the manufacture of the closure by moulding. The closure
2 may be ejected from a mould using local expansion. This allows for faster cycle
time and/or a cheaper mould.
[0067] With reference to Figure 10, the closure 2 and neck of the container are dimensioned
so that when the closure 2 is attached to the neck, the threads 34 are forced radially
outwardly by the neck. This urges the parts of the side wall 6 having threads outwardly.
The regions 46 of the side wall 6 not provided with threads are drawn radially inwardly,
since the circumference of the side wall 6 is substantially constant. The closure
2 is therefore deformed when engaged to the container by relative rotation between
the closure 2 and container.
[0068] When the closure is fastened to the container, the closure 2 is deformed from being
circular in a plan view to the approximately squared shape shown in Figure 10. The
side walls 6 in a non-deformed state have a constant radius of curvature. The outside
of the side wall 6 in the deformed state defines areas 50 having a larger radius of
curvature, which can be considered as flattened portions. The flattened portions 50
are generally still curved, i.e. not planar, with a radius of curvature larger than
the original non-deformed closure 2.
[0069] Between each flattened portion 50 is an area 52 of reduced radius of curvature. The
areas of reduced radius of curvature can be considered as peaked areas 52. The peaked
areas 52 coincide with the groups of threads 34.
[0070] The presence of the flattened portions 50 and peaked areas 52 improves the ease of
purchase of the closure 2 by a user. The flattened portions 50 and peaked areas 52
allow a better grip to be obtained on the side wall 6 by a user than on a cylindrical
closure. This allows the force to be applied more easily by a user to turn the closure
relative to the container. This may be of particularly benefit to elderly people,
or anyone who has difficulty obtaining a grip on a cylindrical exterior of a conventional
closure.
[0071] The closure 2 may retain none, some or all of its deformity after removal from the
neck of the container.
[0072] Figure 11 shows a cross section through the closure 2 along a line A-A through regions
46 shown in Figure 10. The top 4 of the closure retains a generally circular shape
as the closure 2 is attached to the neck. The side wall 6 at the flattened portions
50 is forced inwardly. The amount of deflection of the side 6 is greatest in the centre
of the flattened portions 50. Diametrically opposite distal ends 64 of the closure
2 are spaced closer than diametrically opposite points on the side wall 6 adjacent
the top 4.
[0073] Figure 12 shows a cross section through the closure 2 along a line B-B through the
threads 34. The top 4 of the closure retains a generally circular shape as the closure
2 is attached to the neck. The side wall 6 at the areas 52 is forced outwardly. The
amount of deflection of the side 6 is greatest in the centre of the peaked areas 52.
Diametrically opposite distal ends 64 of the closure 2 are spaced further apart than
diametrically opposite points on the side wall 6 adjacent the top 4.
[0074] The closure 2 is typically formed of a polymeric material, and in particular PLA.
The material may have a cellular microstructure, for example a closed cellular structure.
A closed cellular structure may be achieved by using a blowing agent, to create a
foamed material.
[0075] The person skilled in the art will recognise that a variety of polymers may be used
as the polymeric material in the present invention. Some other examples of polymeric
materials have been listed previously.
[0076] The polymeric material of the closure may be foamed particularly adjacent the top
4 in the radially outer areas of the closure, where the top 4 and side wall 6 adjoin.
This region may be thicker than other parts of the closure 2, for example for the
part 704. However, the closed cellular structure is applicable to all the embodiments
of the closure.
[0077] The foaming increases the resistance of the closure 2 to shattering upon an impact.
The foamed material may be less brittle than a non-foamed material, increasing its
ability to withstand a shock load.
[0078] The closure may be provided with a tamper evident means. The tamper evident means
may be a ring which becomes detached from the closure when the closure is first removed
from the container. A shrink sleeve may be applied and heated onto the container.
Any known tamper evident means may be used with the closure.
[0079] The top 704 has been described as integrally moulded. Alternatively, the top 704
may be formed of a material of substantially uniform thickness as indicated by line
760. The volume indicated between line 760 and line 740 may be filled with a separate
piece of material. The separate piece of material may be inserted or pressed onto
the top 704. The separate piece of material may by rubber, polyethylene, polyethylene
foam or another material. The top 704 may have features to assist the separate piece
of material to adhere.
[0080] Figure 13A shows a further embodiment of the closure 1302. The closure 1302 has a
top 1304 which is domed, the domed section centred on the central axis of the closure.
The domed section has its convex side towards the side wall 1306. The closure 1302
may be used with a container storing carbonated drinks. The domed section can exert
force to the angled sealing surface when urged by pressure in the container caused
by carbonation or other pressurised gas.
[0081] Figure 13B shows an alternate embodiment of part of the closure of Figure 13A. The
top 1304 of Figure 13B has a flattened section 1360 on the periphery of the domed
section. The flattened section 1360 may control transfer of force from the domed section
to the angled sealing surface.
[0082] The groove 405,705,805 and equivalent in other embodiments has been described as
opening to the planar surface of the top of the closure. Alternatively, the groove
may be filled with a separate filling material. The filling material may prevent dirt
accumulating in the groove. The filling material is preferably deformable to allow
the annular projection to deform.
[0083] The filling material may be readily deformable such that the annular projection is
readily deformable. An example of a suitable material is polyethylene foam, although
any suitable material may be used. Alternatively, a filling material may be provided
which requires more force to deform. Such a material would cause the annular projection
to require more force to deform. This may be advantageous to control the deformation
of the annular projection. An example of such a material is rubber, although any suitable
material may be used.
[0084] The following is relevant to any aspect or embodiment of the invention.
[0085] The closure or at least part of the closure will typically be formed from a polymeric
material such as a thermoplastic or thermosetting material. A thermoplastic material
is, however, preferred. Advantageously, the thermoplastic polymeric material comprises
polylactic acid (PLA) (also known as poly(lactide) or poly(lactic acid)) or a derivative
thereof. This material has suitable mechanical, chemical and barrier properties and,
furthermore, is an environmentally friendly material.
[0086] The skilled person will recognise that many suitable polymers can be used in conjunction
with the present invention, either by themselves or as a blend. Some other examples
of polymeric materials include PHA (poly hydroxy-alkanoate, which is also a biodegradable
polymer), polyethylene (including high density polyethylene (HDPE)), polypropylene
and poly(ethylene terephthalate).
[0087] The inventor has found that it is advantageous if the polymeric material (e.g. PLA)
is amorphous or at least partially amorphous. This has been found to result in improved
mechanical properties. In particular, it has been found that a closure formed from
a polymer having a high degree of crystallinity can be difficult to remove from the
container, for example a plastic bottle with a screw thread attachment. Moreover,
a highly crystalline polymer closure can fracture when it is attached to the container.
A highly crystalline polymer may also result in the closure locking up or jamming
on the bottle. Having identified this problem the inventor have found that improved
mechanical properties can be achieved if the degree of crystallinity (volume) in the
polymeric material is preferably less than 50 %, more preferably less than 30 %, still
more preferably less than 20 %.
[0088] The degree of crystallinity in the polymer material forming the closure may be reduced
in a number of ways. For example, if the closure is formed by injection moulding or
compression moulding, then desirable results can be achieved by ensuring that the
mould cavity is filled relatively quickly, for example in ≤ 1 second, preferably ≤
0.5 seconds. Moreover, it is preferable that heat is removed from the closure, once
moulded, as quickly as possible. Heat can be conducted away from the moulded closure
through the mould parts, for example the metal core and cavity. Cooling means are
preferably provided to cool the metal core and cavity. It is also preferable if the
wall section of the moulded closure is ≤ 2 mm, preferably ≤ 1 mm.
[0089] The closure is preferably integrally formed from the polymeric material (e.g. PLA).
[0090] As to manufacture, the closure may, for example, be injection moulded or compression
moulded.
[0091] In use, the closure 2 is screwed onto the neck 20 of the container 22. The closure
2 is attached to the neck 20 be means of threads and grooves 8, 34. One or more edge(s)
or radiussed surface(s) of the neck engages against one or more angled surface(s)
provided in the inside of the closure. The end of the neck does not directly engage
against the top 4 of the closure. The closure then seals the opening 28. If a second
angled surface is provided on the top 4, then the second angled surface simultaneously
engages with a second edge or chamfered surface of the neck 20. The angled surface
12, 412 and/or neck 520 may be elastically deformable to improve the seal around the
opening 28.
[0092] Although the closure has been described in one embodiment as having a single angled
surface facing in part radially outwardly, the closure may alternatively have a single
angled surface of any one of the embodiments facing radially inwardly. A radiussed
surface may be provided in place of edge 26, in combination with an edge 24. Thus,
any combination of one or two angled surfaces, of which one or both may be hollow,
and edges or radiussed surfaces of the neck, may be used. Any combination of convex
or concave arcuate angled surfaces, or a straight-line profiled angled surfaces, with
any radiussed or chamfered surface or edge of the neck may be used. In particular,
a closure with an angled surface having a straight-line profile may be used in combination
with a neck with a radiussed edge.
[0093] Although the closure is described as provided with an annular angled surface, the
angled surface may be any shape to fit the neck of the container, for example substantially
square, oval or rectangular.
[0094] The attachment means may be a hinge pivotally connecting the closure and container,
i.e. a flip-top. The attachment means may also comprise a projection extending radially
inwardly from the side wall of the closure engageable with a projection extending
outwardly from the neck of the container, i.e. a snap-cap.
[0095] The closure has been described as deformable whey screwed onto a container into the
shape illustrated in Figure 10. The closure 2 may alternatively be formed in the state
illustrated in Figure 10. In this embodiment, the closure 2 is not deformed when attached
to the neck, but permanently maintains the shape illustrated in Figures 10 to 12.
[0096] The closure 2 has been described as deformable to the shape illustrated in Figure
10 when attached to a container. Alternatively, the closure and container may be dimensioned
such that there is substantially no deformation of the closure on attachment to a
container. Alternatively, the closure may be permanently shaped as shown in Figures
10 to 12. The flattened surfaces improve the ease with which the closure can be removed
from the container. The side wall of this closure is preferably formed of a material
having a uniform thickness.
1. Verschluss (2; 702) zum Verschließen einer Öffnung (28) eines Behälters (22), wobei
der Verschluss umfasst:
ein Befestigungsmittel (8; 34), um im Gebrauch den Verschluss am Behälter zu befestigen;
eine Dichtfläche (712; 812), die zu einer zur Mittelachse (A-A) des Verschlusses senkrechten
Ebene geneigt ist und derart angeordnet ist, dass dann, wenn der Verschluss an dem
Behälter durch das Befestigungsmittel befestigt wird, die Dichtfläche mit dem Behälter
in Eingriff bringbar ist;
worin die Dichtfläche an einem sich vom Verschluss erstreckenden Vorsprung (710; 810)
vorgesehen ist,
wobei der Vorsprung eine Vertiefung (705; 805) aufweist;
dadurch gekennzeichnet, dass
der Verschluss einen Anschlag (707; 807) aufweist, so dass im Gebrauch der Anschlag
eine Bewegung des Halses relativ zum Verschluss begrenzt; und
der Verschluss ferner eine Nut (736; 836) aufweist, die zwischen dem Anschlag und
der Dichtfläche angeordnet ist, so dass der Hals die Dichtfläche an einer Position
mit Abstand von dem Anschlag kontaktiert.
2. Verschluss nach Anspruch 1, worin die Dichtfläche von der Mittelachse des Verschlusses
radial auswärts weist.
3. Verschluss nach Anspruch 1 oder Anspruch 2, worin das Befestigungsmittel (8; 34) ein
oder mehrere Schraubgewinde oder Nuten aufweist.
4. Verschluss nach einem der vorhergehenden Ansprüche, worin der Verschluss eine Begrenzungsfläche
(744) aufweist, die im Wesentlichen zur Dichtfläche weist, so dass dann, wenn der
Hals die Dichtfläche kontaktiert, die Begrenzungsfläche benachbart dem Hals angeordnet
wird, um eine wesentliche radiale Bewegung des Halses zu verhindern.
5. Verschluss nach einem der vorhergehenden Ansprüche, worin zumindest ein Teil des Verschluss
aus Polymermaterial gebildet ist, wobei das Polymermaterial Polymilchsäure (PLA) oder
ein Derivat davon aufweist.
6. Verschluss nach einem der vorhergehenden Ansprüche, worin der Verschluss ein oberes
Teil aufweist, welches kuppelförmig ist.
7. Behälter (22), kombiniert mit einem Verschluss nach einem vorhergehenden Anspruch,
worin der Behälter einen eine Öffnung (28) definierenden Hals (20; 720) aufweist;
wobei der Verschluss die Öffnung mit dem Hals in Eingriff mit der Dichtfläche des
Verschlusses verschließt.
8. Verschluss und Behälter nach Anspruch 7, worin der Hals (20; 720) des Behälters (22)
eine Radiusoberfläche aufweist, wobei die Radiusoberfläche mit der Dichtfläche des
Verschlusses in Eingriff bringbar ist.