Container of wipes with a ‘fallback prevent’ dispensing nozzle

Abstract

The invention relates to a dispensing nozzle 2 for a container of wipes (not shown). The nozzle 2 features an annular projection 14 the inside of which features inward facing spikes 17. The spikes can be made from a flexible elastomer or a non flexible polypropylene material. The spikes 17 feature slit sections of weakness that enables the spikes to flex upwardly when subjected to upward pressures from say a wipe (not shown) passing though the structure of the dispensing nozzle 2. If downward forces act on the wipe after it has been inserted into the nozzle so as to force the wipe 4 back into its container, two things happen. 1) The spikes 17 or spikes flex back to their original position thereby imposing space restrictions within the annular projection that imped wipe fall back. 2) The ends 20 of the spikes 17 dig into the wipe thereby impeding wipe fall back still further.

Claims

1. A dispensing container for wipes with a dispensing nozzle comprising: a housing which in use receives wipes, said wipes being formed of sheets the ends of said wipes being releasably attached to each other in a series which are capable of being detached into separate wipes when subject to a separation force, the dispensing container has a resilient dispensing nozzle which has an annular projection featuring an aperture at its tip, in use a wipe can be withdrawn from the dispensing container through the aperture of the nozzle, the nozzle exerting sufficient gripping force on the wipe so as to enable or promote the separation of one wipe from its adjacent wipe, one or more spikes or projections are deployed within the dispensing nozzle having their base on the inner surface of the annular projection, one or more spikes or projections being able to flex between a first position, that of the one or more spikes or projections being generally pointing towards the center of the aperture and a second position, that of the one or more spikes or projections being generally at an angle of greater inclination in the direction to the passage of the wipe as it is withdrawn from the dispensing container through the aperture of the nozzle, the shape of the spikes or projections being such that as they flex to their second position during normal use the wipe material can occupy all gaps within the dispensing nozzle through which the wipes can exit the dispensing container, its bending moment being such that it requires less force to flex the one or more spikes or projections from their first position to their second position than it takes to flex the one or more spikes or projections from their first position to their third position wherein the ends of the one or more spikes or projections are generally at an angle inclined in the direction opposite to the passage of the wipe as it is withdrawn from the dispensing container, the difference in bending moment of one or more spikes or projections is caused by at least the shape/angularity of the spikes or projections which when considered in radial cross section feature an angle between the annular projection and the top surface of the spike or projection which is greater than the angle between the annular projection and the lower surface of the spike or projection.

2. A dispensing container for wipes according to claim 1 wherein the wipes are releasably attached to each other by the adhesion or cohesion of a viscous substance, a line of perforations, frictional forces arising from being interleaved, or any combination of the aforementioned.

3. A dispensing container for wipes according to claim 1 wherein the ends of one or more spikes being generally of a non arcuate, narrow pointed shape.

4. A dispensing container for wipes according to claim 1 wherein the underside of the spikes form a funnel shaped structure.

5. A dispensing container for wipes according to claim 1 wherein the nozzle features a combination of ribs, pips, spikes, projections, raised or roughened region or other gripping means together.

6. A dispensing container for wipes according to claim 1 wherein the aperture is formed from a flexible elastomeric material and is expandable being biased towards a contracted state as the wipe is extracted.

7. A dispensing container for wipes according to claim 1 wherein the dispensing nozzle is made from a single material in a single shot injection moulding process.

8. A dispensing container for wipes according to claim 1 wherein the spikes are formed from a plastic material like polypropylene or HDPE.

9. A dispensing container for wipes according to claim 1 wherein the walls of the nozzle taper inwards from a widened base and then curve outwards into an annular projection which features an aperture at its tip.

10. A dispensing container for wipes according to claim 9 wherein the widened base is dome shaped.

11. A dispensing container for wipes according to claim 1 wherein the difference in bending moment of one or more spikes is at least because they feature areas of weakness about which the spikes flex from their first to their second positions.

12. A dispensing container for wipes according to claim 11 wherein the area of weakness that causes the difference in bending moment of the one of more spikes or projections is due to the presence of a slit in the structure of the one or more spikes or projections, which enables the one or more spikes or projections featuring the slits to flex to their second position.

13. A dispensing container for wipes with a dispensing nozzle comprising: a housing which in use receives wipes, said wipes being formed of sheets the ends of said wipes being releasably attached to each other in a series which are capable of being detached into separate wipes when subject to a separation force, the dispensing container has a dispensing nozzle with an aperture at its tip, in use a wipe can be withdrawn from the dispensing container through the aperture of the nozzle, the nozzle exerting a gripping force of sufficient magnitude on the wipe so as to enable or promote the separation of one wipe from its adjacent wipe, one or more spikes are deployed within the dispensing nozzle, the spikes featuring a wider section at a point closer to its base that then tapers to a narrower apex, the one or more spikes being able to flex between a first position, that of one or more spikes being generally pointing towards the center of the aperture and a second position, that of the one or more spikes being at an angle of greater inclination in the direction to the passage of the wipe as it is withdrawn from the dispensing container through the aperture of the dispensing nozzle, the bending moment of the one or more spikes is such that it requires less force to flex the one or more spikes from their first position to their second position than it takes to flex the one or more spikes from their first position to their third position wherein the ends of the one or more spikes are generally at an angle inclined in the direction opposite to the passage of the wipe as it is withdrawn from the aperture of the dispensing container, the difference in bending moment of one or more spikes is at least because they feature areas of weakness about which the spikes flex from their first to their second positions.

14. A dispensing container for wipes according to claim 13 wherein the shape of the spikes or projections is such that as they flex to their second position during normal use the wipe material can occupy all of the exit gaps of the dispensing nozzle.

15. A dispensing container for wipes according to claim 13 wherein the wipes are releasably attached to each other by the adhesion or cohesion of a viscous substance, a line of perforations, frictional forces arising from being interleaved, or any combination of the aforementioned.

16. A dispensing container for wipes according to claim 13 wherein the spikes are formed from a plastic material like polypropylene or HDPE.

17. A dispensing container for wipes according to claim 13 wherein the dispensing nozzle is made from a single material in a single shot injection moulding process.

18. A dispensing container for wipes according to claim 13 wherein the aperture, being formed from a flexible elastomeric material, is resilient and expandable being biased towards a contracted state as the wipe is extracted.

19. A dispensing container for wipes according to claim 13 wherein the nozzle features a combination of ribs, pips, spikes, projections, raised or roughened region or other gripping means together.

20. A dispensing container for wipes according to claim 13 wherein the underside of the spikes form a funnel shaped structure.

21. A dispensing container for wipes according to claim 13 wherein the ends of one or more spikes being generally of a non arcuate, narrow pointed shape.

22. A dispensing container for wipes according to claim 13 wherein the area of weakness that causes the difference in bending moment of the one of more spikes or projections is due to the presence of a slit in the structure of the one or more spikes or projections, which enables the one or more spikes or projections featuring the slits to flex to their second position.

23. A dispensing container for wipes according to claim 13 wherein the difference in bending moment of one or more spikes or projections is caused by at least the shape/angularity of the spikes or projections which when considered in radial cross section feature an angle between the annular projection and the top surface of the spike or annular projection which is greater than the angle between the annular projection and the lower surface of the spike or projection.

24. A dispensing container for wipes according to claim 13 wherein the walls of the nozzle taper inwards from a widened base and then curve outwards into an annular projection which features an aperture at its tip.

25. A dispensing container for wipes according to claim 24 wherein the widened base is dome shaped.

26. A dispensing container for wipes according to claim 24 wherein the one or more spikes or projections deployed within the dispensing nozzle has its base on the inner surface of the annular projection.

Description

DETAILED DESCRIPTION OF THE INVENTION

(1) Embodiments of the invention will now be described with reference to the accompanying drawings in which:

(2) Referring to FIG. 1 there is shown a top view of a Rigid Flip Top (RFT) A attached to a hermetically sealed soft pack dispensing container of wipes B. The soft pack is generally cuboid, having two similar rectangular sides (only one side 8 being here visible), two ends 5, 6, and an upper face 7, and lower face 8 (not shown). The soft pack contains a stack of wipes (not shown) encapsulated by an outer covering of flexible, impermeable material, typically formed from a sleeve of material bonded at each of the ends 5, 6, so that the soft pack is hermetically sealed, apart from the opening through the RFT A.

(3) The soft pack has an RFT A bonded to the upper face 7.

(4) The RFT A features a central dispensing nozzle 2 covering the aperture (not shown) of the soft pack of the lid C container. The central nozzle 2 is shown with the tail of a wipe 4 protruding through its opening 3. The opening 3 may be sealed using a sealing cap 1 here shown in open position.

(5) Referring to FIG. 2 there is shown cross section views of stacks of wipes 3 within a container B. The container B (which conveniently is shown to be of cuboid shape), can be made from a soft flexible material or a less flexible polypropylene material.

(6) The wipes 4 shown in FIG. 2a are in a folded format. The individual wipes are here shown separated by lines of perforations 10. However the length of wipe material that is shown in the stack could feature some other method by which the sheets are bonded together along all or part of its length, like a mild adhesive or bonded together due to the viscosity of liquid that impregnates the wipe material, or due to the friction between the interleaved sheets. The stack of wipes 4 could perhaps feature a combination of mild adhesive, lines of perforations or liquid impregnate viscosity or interleaved formation bonding the individual sheets together.

(7) The wipes 4 shown in FIG. 2b are in a folded, interleaved format 11, the back end of each individual wipe is interleaved with the front end of the trailing wipe. The interleave can be in the form of C fold, Z fold Quarter fold or any other folded format as well known to those skilled in the art. As the top wipe is extracted from the container, the frictional action of the interleave connection between the wipes is enough to pull the trailing wipe towards the opening (not shown) of the container B. If the wipes are impregnated with a liquid, forces of viscosity between the ends of the wipes would further enhance the bond between them as would the addition of a mild adhesive applied to the ends of each individual wipe. The stack of wipes 4 could perhaps feature any combination of mild adhesive, lines of perforations or interleave connection bonding the individual sheets together.

(8) Referring to FIG. 3 there is shown a cross section view of a container of wipes which is in the form of a cylindrical canister B featuring a removable cap C and contains a roll of wipes D.

(9) The lid C has a central dispensing nozzle 2 which covers the opening of the lid C on the upper face 13. The nozzle 2 is shown with the tail of a wipe 4 protruding through its opening 3. The aperture may be sealed using a sealing cap (not shown). The nozzle 2 can be made from a flexible elastomeric material or a less flexible material like polypropylene. The roll of wipes D will typically feature lines of perforations 10 separating the roll into single sheets, and the wipe material will feed through the opening of the container 12 then through the nozzle 2 from the central core of the roll D. However the roll of wipes D could feature some other method by which the sheets are bonded together along all or part of its length, like a mild adhesive. The roll of wipes D could perhaps feature a combination of mild adhesive and lines of perforations bonding the individual sheets together.

(10) The canister B and lid C could be in the form of a more rigid housing, one that is either portable or alternatively fixed to a horizontal or vertical surface.

(11) The dispensing nozzle 2 may be in a form such that it can be retro-fitted to the lid C or permanently bonded to it by way of a single or two shot mold process.

(12) Referring to FIG. 4 there are shown two cross section views of a dispensing nozzle 2. The nozzle 2 is shown to feature an annular projection 14 attached to a dome shaped structure 15. The nozzle 2 could be fixed within a Rigid Flip Top (not shown) which itself would be fixed over the opening to a soft pack container like that shown in FIG. 1 or the lid of a canister of wipes like that shown in FIG. 3. The inside wall of the annular projection 14 features protuberances 16 and spikes 17. The spikes 17 feature a one-way hinge like point of weakness axis 18 resultant from a slit 19 in the structure of the spike 17 which extends to the axis of the spike 18.

(13) FIG. 4a shows an upward facing dispensing nozzle 2 with a relatively wide base 15 which tapers radially inwards and then smoothly curves upwards into the annular projection 14 which terminates at the tip to provide an opening 3 for the wipes' exit.

(14) The widened dome shaped base enables easy feed of the first wipe. It also facilitates graceful passage of the wipes into the annular projection.

(15) This is because as a wipe is extracted from the top of a stack of wipes, the outsides of the wipe near the perimeter of the container are pulled towards the centre of the stack and form a conical shape prior to exiting the container through the narrow annular projection. The nozzle having a widened base which curves outwards into an annular projection enables the sections of the wipe on the outside sections of the stack to enter the restrictive, narrow annular projection more gradually, more smoothly, more gracefully. This thereby reduces the possible incidence for the wipe to separate prematurely. Should the wipe enter the annular projection from a more acute angle, the corner, at which the base of the annular projection is formed, could exert pressures on the moving wipe that result in premature separations of the wipes.

(16) However a consequence of a dome structure is that the space between the outset of the annular projection and top of the stack of wipes is thereby increased, which could provide greater opportunity for the wipe to fall back into the container. The barbed action of the spikes or projections and their return to position 1 if the wipe is subjected to downward forces impedes the wipe from falling back. The combination of the widened dome shape together with the annular projection featuring the spikes thereby enables the user to gain the advantages of easier feed of the first wipe and smoother passage of the wipe from the container without increased risk of the wipe falling back into it.

(17) The spikes 17 and protuberances 16 deployed on the inside walls of the annular projection 14 are there to help bring about rupturing of the bonds between the wipes (not shown), e.g. their perforations, to enable the web to separate into single sheets. The underside of the spikes 17 is of a smooth curved shape to aid the passage of the wipe up through the annular projection 14 and prevent premature rupturing of the bonds between the wipes. The spikes are generally pointing inwards towards the centre of the annular projection 14, their first position.

(18) FIG. 4b shows the spikes 17 in their second position, here shown as being at an upward/centrally facing angle having been subjected to upward pressures due to say, a wipe being withdrawn from the container through the annular projection 14. The axis 18 is on the upper section of the spike 17, therefore the spike 17 can freely move upwards as upward pressure is applied to it.

(19) However greater force would be required to move it from its first position to its third position wherein the ends of the spikes are at an angle in the general direction opposite to the passage of the wipe as it is withdrawn from the housing container. This is because, as can be seen in FIGS. 4a & 4b, if the spikes are subjected to downward forces, the bases of the spikes 17 would abut the inside wall of the annular projection 14.

(20) Should a wipe (not shown) that has entered the annular projection 14 be subject to any downward pressures that could force the wipe to slip downwards into the container, the pointed ends 20 of the spikes 17, which are in their second position, would impact and dig into the falling wipe as the spikes 17 return towards their first positions. The return of the spikes 17 towards their first positions then reduces the size of the gap between the ends of the spikes 20 which therefore further curtails the fall of the wipe.

(21) The shape of the annular projection 14 is here shown to have parallel sides however it could be teat-like or conical or any regular or irregular shaped annular projection.

(22) FIG. 5 shows various perspectives of a variation of the nozzle shown in FIG. 4, one that features spikes 17 without additional protuberances 16.

(23) Referring to FIG. 5a, there is shown a downward side view of the head of a dispensing nozzle 2 prior to insertion of a wipe. The spikes 17 are in their first position, that of being generally pointing towards the centre of the aperture but also inclined at an angle in the direction of the wipe as it is withdrawn from the housing container. This small upward angularity is more clearly shown in FIG. 5b and FIG. 5c.

(24) This slight upward curve in the shape of the spikes could help make feeding of the first wipe a little easier and as can be seen a little more clearly in FIG. 5c, it enables the underside of the spikes to more easily form a funnel shape to help with the passage of the wipes through the annular projection.

(25) Referring to FIG. 5c there is shown spikes 17 in their first position slightly inclined in the direction of the passage of the wipe out though the container. The spikes feature slits 19 that form the axes 18 about which the spikes 17 can flex upwards to their second position when upward pressures are applied to the ends of the spikes 20. So as a wipe passes though the annular projection 14, the spikes flex upwards about their axes 18 to their second position, wherein the spikes are at a greater angle in the direction to the passage of a wipe out of the container.

(26) Greater force would however be required to move the spikes 17 downwards from their first position to their third position, wherein the spikes are generally at an angle inclined in the direction opposite to the passage of a wipe as it is withdrawn from the housing container.

(27) This is because as downward forces are applied to the spikes, their bases abut the inside wall of the annular projection 14 which therefore impedes downward movement of the spike. The points of weakness axes 18, coupled with the wider base of the spikes abutting the inside of the annular projection 14 therefore enables the spikes to act like a one-way valve. The larger the surface area of the base of the spike the deeper the slit can be and ipso facto the greater the surface area that the lower base of the slit 24 can abut the inside wall of the annular projection or the stump 25 of the spike as shown in FIG. 5e.

(28) Having the spikes featuring their slit line of weakness deployed on the inside wall of an annular projection enables the spikes to feature larger bases and the more robust the structure of the spikes, the more efficaciously they can resist pressures to force them into their third position.

(29) So incorporating an annular projection into their structure enables the manufacturer to build dispensing nozzles that are can both prevent wipe fall back for both light and heavy substrates and make them less likely to permit the user or curious small children to injure themselves by pushing their fingers back through the opening 3 of the nozzles and entrapping them.

(30) The point 23 at which the dome 15 curves smoothly upwards into the annular projection 14 is shown to be of graceful curved shaping in order to minimize the impact it has on the exiting wipe and thereby reduce the chances for premature rupturing of the perforation line.

(31) Referring to FIG. 5d, there is shown a cross section view of nozzle 2 featuring slits 19 that form axes 18. The spikes 17 are in their first position, that of generally pointing towards the centre of the annular projection.

(32) The angle 21 is greater than the acute angle 22, angle 21 preferably being greater than 90 degrees. This shaping therefore makes it even more difficult for pressure to move the spikes into their third position

(33) Referring to FIG. 5e, because of the nature of the spikes and the annular projection, which could be comprised of an elastomeric or a less flexible material like polypropylene, upward pressure applied to the end of the spike 20 as a wipe (not shown) is inserted into the nozzle 2 causes the slits 19 to agape and for the spikes 17 to therefore flex about their axes and point in the general direction of the passage of the wipe through the annular projection, their second position. The walls of the annular projection 14 then allow passage of the wipe through its structure.

(34) Downward pressures applied to the agape spikes in their second position force the spikes back towards their first position causing the agape base of the spike 24 to abut the stump 25 of the spike thereby deterring the spike to flex to its third position, giving this dispensing nozzle iteration its one-way valve properties.

(35) The spikes 17 are deployed on the inside of the annular projection 14. The wider the annular projection 14, the greater the surface area the base of the spike 17 can be and therefore the deeper the slit 19 can be. Ipso facto the wider surface of the agape base of the spike 24 that can abut the stump 25. This increased surface area contact between the base 24 and the stump 25 increases the level of resistance the spikes can provide to forces acting in the opposite direction to direction of the wipe exiting the container.

(36) The architecture of the nozzles 2 featured in FIG. 5 enables the dispensing nozzle units to be adapted to various wipe types by altering the variables within their structure. By increasing the width of the annular projection 14, wipes of different widths and thickness can be accommodated. Increasing the surface area of the base of the spikes 17 deployed on the inside of the annular projection increases the resistance of the spikes to downward pressures. By increasing the length of the spikes 17, the resistance that the spikes apply to the exiting wipe can be increased. By shortening the length of the spikes 17, less pressure can be applied to exiting wipe and wipes can be more easily fed through the opening 3. By making the spikes 17 from a more flexible material the resistance that the spikes apply to the exiting wipe can be increased. By increasing the width of the axis 18, its depth of flex, more resistance can be applied to the exiting wipe and visa versa.

(37) It is therefore implicit that there is an inverse relationship for a given aperture width between the length of the spikes and the depth of flex/resistance level at the area of weakness. This relationship can be used in order for manufacturers to establish the desired level of ease of feed that they want to offer their customers without compromising the level of resistance to the exiting wipe required in order to bring about wipe separation. For a given diameter of annular projection, the spike length can be reduced to make the opening 3 wider, opening 3 being defined by the distance between the tips of the spikes 20 when in their first positions. The depth of flex can then be increased in order to restore the level of resistance applied by the spikes to the wipes in order to bring about their separation. So for a given level of pressure required to separate the wipes, the greater the level of resistance provided at the area of weakness, the shorter the spikes 17, (and therefore the wider the opening 3), can be prior to insertion of the wipe.

(38) So having a specific line/section of weakness about which the spikes flex confers many advantages including:

(39) 1) Enabling easier design of dispensing nozzles because variables like the depth of flex, the length of the spike etc very specific variables that can be adjusted and yield predicable results. If the flexibility of the spikes were reliant solely on the tapered design of the underside of the spike, as is disclosed in US 2010/0133287 A1, lines 9-12, the rate at which the spike tapers and how each change effects the way the spike arc flexes would also need to be considered which would make finding the correct length of spike/resistance to flex ratio a more complicated process.

(40) 2) Enabling the spikes to be of a more rigid strength throughout their structure. This design of spike might particularly suit wipes made from heavier substrate types because the spikes can therefore be of a more robust strength. Spikes that are reliant on a tapering shape for their flexibility as is disclosed in US 2010/0133287 A1 might buckle at thinner parts of their structure when subjected to downward forces from heavier substrate types.

(41) 3) Enabling the easier choice as to the degree to which the spikes should flex to their second position. Again, by altering a single variable, e.g. the depth of the line of flex, the spikes will flex more or less as required as the wipe passes through the aperture. The greater the angle of flex, the greater the degree to which forces from the underside of the spikes will play in separating the wipes, and the less the wipe separation process will be due to penetration of the web by the sharp ends of the spikes. By playing a much reduced part in the wipe separation process, these sharp ends therefore have much reduced opportunity to damage the fabric of the wipe as it passes over them. This may be more appropriate for delicate substrates that could be damaged due to the impact of sharp spikes as the web passes over them on its way out of the container.

(42) The acute angle of the lower side of spikes 17 as shown in FIGS. 4 & 5 confers two important benefits.

(43) 1) As can be seen particularly in FIGS. 5c and 5d, the lower sides of the spikes 17 are at an acute angle, angle 22. This means that the lower sections of the spikes 17 form a sort of funnel. As a wipe (not shown) passes through the annular projection 14, the funnel shaping created by the acute angled underside of the spikes encourages the exiting wipe material to fill the now wider, triangular gaps between the spikes on its passage out through the annular projection. After the exiting wipe separates from the web, the tail of the emerging wipe, which now occupies the triangular shaped gaps between the spikes, slips back a little thereby helping to settle the wipe material into the open, triangular shaped gaps between the spikes. This ipso facto helps seal the container which thereby deters wipe dry out.

(44) 2) Because the spikes flex upwards, the gaps between the spikes open up and the wipe material spreads itself into these gaps. Therefore ipso facto a greater surface area of the exiting web and its perforation line come into close contact with the ends of the spikes 20. This therefore enables the ends of the spikes 20 to more effectively penetrate and bring about rupturing of the perforation line which thereby encourages wipe separation.

(45) If the spikes 17 were less flexible and not shaped with an acute angle 22 to the lower surface, the web would not be encouraged to fill the gaps between the spikes 17, instead the wipes would be inclined to exit the container in a more compact, cylindrical format. The perforation lines would thereby be much less exposed to the ends of the spike 20, which then lessens their ability to penetrate and rupture the perforation line to bring about wipe separation.

(46) Prior Art disclosures such as US 2015/048105 A1 (Michael John Gordon GB) 19 Feb. 2015 and US 2010/133287 A1 (Tramontina Paul Francis US) do not mention or intimate the presence of slits or other points of weakness to enable the spikes to flex in the direction of the passage of a wipe through the structures of their dispensing nozzles or that the shape of the spikes or flaps feature a lower section with an acute angle, angle 22, that enables the spikes to form a sort of funnel shape, as shown in FIG. 5.

(47) In all of FIGS. 4 & 5, the annular projection 14 with protuberances 16 and spikes 17 on its inside wall and the dome like structure 15 to which the annular projection 14 is firmly attached could both be made from the same material or from a mixture of materials. The annular projection 14 with protuberances 16 and spikes 17 could be made from a flexible elastomer, and the dome like structure 15 to which the annular projection 14 is firmly connected could be both made from a more rigid material like polypropylene or HDPE. Alternatively the various components of the dispensing nozzle 2 could be made from a single flexible or single more rigid material or the dispensing nozzle could be comprised of components made from a variety of flexible and more rigid materials built into the same dispensing nozzle structure.

(48) Throughout this disclosure, whenever the spikes are in their first position, the spikes based valve-like structure helps seal the pack in order to keep the wipes within the container moist.

(49) Throughout this disclosure, whenever the spikes feature points of weakness solely to the underside of the base of the spikes, this forms a one-way valve-like structure which makes it harder to force the spikes from their first position to their third position than it takes to force the them to their second position. Ipso facto this structure helps prevent fingers from being pushed into the container while at the same time making a further contribution to preventing wipe fall back into the container.

(50) Additionally the manufacturer of the wipes can vary the strength of the perforations in order to ensure that the wipes dispense successfully through a nozzle type of a specific architecture.

(51) The pointed, tapering nature of the spikes shown here-in means that they offer less resistance at the centre of the aperture and are easier to flex when pressure is applied at that point. There is therefore less need for the opening 3 to be wide enough to thread the first wipe through it. Instead the first wipe can be fed through the aperture by applying pressure to the end of the wipe with the thumb or finger and then pushing said wipe through this weaker centre section of the valve-like formation of the flexible spikes. This can be an easier way to feed a wipe through the nozzle particularly if the aperture features an annular projection with a maze of fixed pips, projections or raised regions deployed on its which may make a threading process more difficult.

(52) Further modifications will be apparent to those skilled in the art without departing from the scope of the present invention.