The present invention relates to liquid containers and closures for liquid containers. More particularly, the invention relates to containers having novel reclosable closures, which may be adapted for use with various fluids, including flammable fluids such as petrol. The invention may be applied in the field of petrol cans or 'jerry cans', used for filling the fuel tank of a motorised vehicle.

It is well known to provide petrol cans to motorists or individuals wishing to transport petrol from a petrol pump to any kind of motorised vehicle, such as a lawnmower, tractor and occasionally to a broken down car. Emergency breakdown services occasionally carry cans full of fuel for refuelling motorists who have run out of fuel away from home. Known fuel cans generally have a single opening through which liquid may be poured into or out of the container and a separately attachable spout for attachment to the opening as an extension, to pour the liquid more directly into the fuel tank of the vehicle. There is a need for an improved closure device for such containers to simplify the transition from a sealed transporting configuration into an open, pouring, configuration of the container. Such closures can also be useful in other areas where fluids are temporarily transported in containers and where it is desired to facilitate fast, convenient, safe and controlled release of the fluid from the container.

According to the present invention there is provided a closure arrangement for a liquid container comprising:

a neck comprising:

a bore; and

a thread, for threaded engagement with a cap;

a cap comprising:

a threaded portion; and

a closure portion configured to close the bore of the neck when the cap is held in a closed position by the thread;

a plurality of apertures for the passage of liquid; and a spout formed integrally with the cap and arranged to collect and direct flow from the apertures;

and sealing means, arranged to prevent liquid from exiting the container via the threads;

the closure portion, being arranged to engage the neck, to prevent fluid flow through the apertures when the cap is in the closed position.

The closure arrangement of the present invention, on rotation of the cap relative to the neck, reveals a pathway from the interior of the container through multiple apertures in a closure, and has an integral spout which can bring together, under gravity during pouring, the multiple streams of liquid dispensed through the apertures into the spout in a single, well directed flow whilst simultaneously allowing air to enter the container to replace the liquid already dispensed.

The apertures may be arranged such that at least a proportion of the apertures are arranged substantially opposite one another. This allows air to enter a container having the closure arrangement through an upper set of apertures during pouring to replace fluid exiting the container through lower apertures during pouring, while the multiple streams are gathered via a spout.

The closure portion may be arranged to engage an end portion of the neck.

The closure portion may be formed either integrally with the cap or as a separate component.

The closure portion may comprise a sealing portion for engagement with the neck to close a flow path from the bore of the neck to the apertures.

The apertures may be located at a smaller diameter than that of the neck or of its bore.

A void may be provided in the closing portion to provide a flow path from the sealing edge to the apertures located at a smaller diameter on the closing portion than that of the sealing edge.

The cap may comprise a spout comprising at least one wall parallel to the threaded portion.

The spout may comprise an outlet orifice having a diameter at least as great as that of the outer diameter of the array of apertures.

The cap may comprise no enclosed volumes. At least one of the thread of the cap or the thread of the neck may be a single start thread.

At least one of the threads of the cap or the neck may be arranged such that a half-turn, a three-quarter turn, or a full turn of the cap from its closed position opens a flow path through the apertures smaller than the flow path through the neck.

The cap may further comprise an outlet orifice and a chamber between the closure portion and the outlet orifice.

The plurality of apertures may have a flow area for the passage of liquid at least substantially equal to the flow area of the outlet orifice.

At least one of the neck and the cap may comprise a multi-start thread.

At least one of the threads of the cap or the neck, may be arranged such that a half-turn of the cap from its closed position opens a flow path through the apertures at least substantially equal to the flow path through the outlet orifice.

The outlet orifice may have a flow area greater than around half the flow area of the bore of the neck, preferably greater than around 3/4 of the flow area of the bore of the neck, more preferably greater than around 5/6 of the flow area of the bore of the neck.

At least one of the neck and the cap may comprise a thread arranged such that turning the cap from the closed position through between a half and a full turn releases the cap from the neck.

The apertures may be arranged to engage an end portion of the neck, such that the end portion of the neck substantially seals the apertures of the closure portion when the cap is screwed on to the thread.

The closure portion comprises bore sealing means arranged to seal the bore of the neck when the cap is in the closed position.

The sealing means may be provided by the threads of the cap and the neck being configured to have an interference-fit, such that the threads of the neck and cap are substantially liquid-tight when engaged with one another.

The sealing means may be provided as a separate sealing member between the cap and the neck.

The closure portion may be a separate component from the threaded portion and may be engaged thereto by engagement means, such as by an interference fit, by threaded engagement, by fastenings, or by adhesive. The neck may be integrally formed on a liquid container, which may be a fuel can.

The invention further provides a liquid container comprising a body and a spout;

the body comprising:

a first opening for filling or pouring liquid from the container; a second opening for venting air into the container;

the spout being movably mounted to the container and movable between first and second positions;

the spout and first and second openings being arranged such that:

in the first position of the spout, the second opening is open and liquid may be poured from the container through the spout; and

in a second position, the first and second openings are closed by sealing engagement with the spout.

The spout may be in threaded engagement with the first opening of the body.

The spout may be arranged to be rotatable from the first position to the second position.

The liquid container may comprise a closure arrangement according to the present invention, the container body comprising the neck and the spout comprising the cap.

The spout may comprise a protrusion arranged to enter the second opening to prevent passage of air through the opening.

The second opening may comprise a resilient seal.

The container may comprise spout retaining means for retaining the spout in the second position.

The spout retaining means may be formed on the spout and on the body of the container.

The retention means may comprise a container extension for surrounding at least a part of the spout and releasable engagement means for engaging the spout with the container extension.

The container may further comprise spout retention means configured to retain the spout in its open position. Specific embodiments of the present invention will be described with reference to the following figures in which:

Figure 1 shows a closure arrangement incorporating features of the invention;

Figure 2A shows an alternative closure arrangement incorporating features of the invention;

Figure 2B shows a further alternative closure arrangement incorporating features of the invention;

Figure 2C shows a further alternative closure arrangement incorporating features of the invention

Figure 3 shows further detail of various sealing means for a closure arrangement;

Figure 4 shows detail of a closure portion of a cap or spout, for use in the present invention;

Figure 5 shows a container suitable for use with the invention;

Figure 6 shows an alternative view of a container for use with the invention;

Figure 7 shows details of a spout for use with the present invention;

Figure 8 shows further detail of a spout for use of the present invention; Figure 9 shows detail of a grommet as incorporated in Figure 7;

Figure 10 shows detail of a container incorporating features of the invention;

Figure 1 1 shows details of a spout for use with the present invention; Figure 12 shows further detail of a spout for use in the present invention; and

Figure 13 shows an assembly for creating a spout for use with the present invention.

Figures 14A to 14D show an alternative arrangement for a spout and spout locking means for the invention.

Figure 1 illustrates a closure arrangement 10 according to an aspect of the present invention. The arrangement comprises a neck 1 1 having a bore 12 disposed therein. The neck 11 further comprises a threaded portion 1 1 1 comprising a thread 1 12. An end portion 1 13 of the neck is located at a distal end of the neck. The arrangement further comprises a cap 2 comprising a threaded portion 21 , which is provided with a thread 211. A closure portion 22 is configured relative to the threaded portion 21 such that when the threaded portion 21 is engaged with the threaded portion 1 11 of neck 11 , closure portion 22 can substantially seal an end of bore 12 of the neck 11 in a closed position. The closure portion 22 further comprises a plurality of apertures 23. The apertures are arranged substantially in alignment with end portion 1 13 of neck 11. This can allow the end portion 113 to substantially seal apertures 23 when cap 2 is screwed into a closed position on threads 211 and 1 12. The cap may be moved between an open position and closed position by rotation of the cap on its threads relative to the neck. In the open position, fluid is free to flow through apertures 23.

Fluid is intended to pass out of the bore 12 through chamber 24 and out via outlet orifice 25 of the cap 2. It is therefore important that liquid is prevented from passing along threads 1 12 and 211 so that fluid exiting the bore 12 is directed through outlet orifice 25 of cap 2. Threads 211 and 1 12 may therefore be configured such that they engage with an interference-fit. This can prevent any fluid passing from the bore 12 to the outside of the neck 11 via the threads. Additionally, or alternatively, a sealing feature 1 14 may be provided on the neck to may engage with cap 2 in an interference-fit to provide a sealing function to prevent fluids from passing from bore 12 to the exterior of the neck via the threads. Closure portion 22 may further be sized and dimensioned to substantially seal the open end of neck 1 1 at its end points 1 13.

Apertures 23 may be sized and dimensioned to allow a flow area through the apertures 23 approximately equal to the flow area through the outlet orifice 25.

A chamfer 115 may be provided on end portion 1 13 of neck 11. A corresponding chamfer at sealing edge 215 may be provided on closure portion 22. This chamfer can assist in increasing the sealing force provided between the closure portion 22 and neck 11 to provide a more effective seal. An angle 116 of the chamfer may be chosen to provide the best balance of sealing performance and opening of the flow path out of the neck 11 through the cap 2 as appropriate. The closer the angle is to the longitudinal axis of neck 11 , the smaller the resulting gap for a given rise of cap 2 in direction of arrow 13. Angle 1 16 may be around 60° or around 70° or between those angles, but may be smaller if sealing force takes precedence over flow area.

The aim of the arrangement of the threads 21 1 is to configure them such that when the cap 2 is turned through a half turn, i.e. through approximately 180°, the cap opens the gap between closure portion 22 and end portion 1 13 of neck 1 1 to a sufficient degree that the flow path from the bore 12 through the apertures 23 to the chamber 24 is substantially equal to the flow path provided through orifice 25, or greater. To assist with this, it can be advantageous to provide a multi-start thread, optionally a two-start thread, but potentially having more than two-starts. As an example, if the pitch of the thread is around 8mm, then a half turn of the cap 2 will provide a rise height of 4mm. However, the dimensions of the neck 1 1 , cap 2, and threads 21 1 and 1 12 can be arranged to provide whatever the desired rise may be.

The threads may further be configured such that further rotation of the cap 2 allows the cap to be completely removed from neck 11. Where desired, the threads can be configured such that the cap 2 may be removed with between a half turn and a full turn from its closed position, alternatively between a half turn and a three quarter turn, or between a three quarter turn and a full turn, or between a two-thirds turn up to any of the above upper limits, from its closed position. If the further amount required to remove the cap is too small, then the cap may not be securely held on the neck during pouring, if it is too great, then it may be difficult or impossible to remove, depending upon the form of the cap and the container to which it is attached. An angle of rotation from a closed position of the cap to one where it is free to be removed may be around 350 degrees.

Figure 2A shows an alternative arrangement for a closure arrangement, which is generally similar to the arrangement shown in Figure 1 , and equivalent features in Figure 2A onwards are given the same reference numerals as used in Figure 1. The arrangement is generally as described with respect to Figure 1 with some small differences. In the arrangement of Figure 2A, outlet aperture 25 is provided to allow an outward flow from chamber 24 in a direction substantially perpendicular to a longitudinal axis of bore 12 of neck 11 and of threads 21 1 and 112. Further, where in the example shown in Figure 1 , closure portion 22 is a separate element from the main body of cap 2, the closure portion 22 is integrally formed with the threaded portion 21. In order to achieve this configuration, it may be necessary to form cap 2 in two separate parts 201 and 202 which are divided by line 203. This can allow the parts to be injection moulded. After moulding, the two parts may be joined alone this line by hot plate welding or sonic welding, or any other suitable means of attaching the two parts together. Therefore, alternative methods of forming the chamber 24 incorporating the enclosure portion 22 are provided.

Figure 2B illustrates a further alternative closure arrangement, which is generally similar to the arrangements shown in Figures 1 and 2A. The closure illustrate in Figure 2B is configured similarly and functions generally in the same manner as that shown in Figures 1 and 2A. The same reference numerals are used for similar features. However, some differences may be introduced as follows. Outlet aperture 25 may be substantially the same size, or larger, than the bore 12 of neck 11 and may, in particular, be substantially larger than the outer diameter of the array of apertures 23. The outer walls of the chamber 24 may be substantially parallel to the walls or threaded portions 1 11 of the neck 11. The chamber may therefore be configured as an open chamber having an open first end opposite the apertures 23. The open chamber may have a sloped edge at its open end, such that a short spout is formed and so the chamber may itself form an open spout. It may not be necessary in the examples shown for the closure to be removable in less than a single turn of the closure. In these cases it can be possible for the threaded portion to contain a single start thread, which is configured to allow a sufficient flow path, as defined above, when the cap is turned through more than a half turn of more than a full turn or even more. Some form of sealing means will be beneficial, in the form of interference fit threads 1 12, 211 , or separate sealing means, arranged to prevent flow of fluid out of the container via the threads.

An advantage of the arrangement shown in Figure 2B is that it can be moulded with simple open-shut tooling having a single axis of motion of the tooling parts. This can be improved if the outer walls of the cap are substantially parallel and the inner walls curve outwardly from the apertures toward the open end of the open spout. The cap may comprise no enclosed volumes, so that moulds can reach all outer surfaces of the cap without the need for complex tooling or manufacturing techniques. This can facilitate release of the cap from the tooling, while also providing the remaining advantages of the closure arrangement described above. The neck of any container to which the cap is provided may require increased strength through the use of stronger materials than are usual and may require modified dimensions to arrive at the correct configuration to provide the desired amount of rotation to open the apertures 23 and to release the cap 2 from the neck 11. The arrangement shown in Figure 2B may be useful in application not requiring an elongate spout as shown in later Figures, such as for garden products of for fuel for vehicles not requiring a spout to open trap doors in the filler opening such as are present on modern road vehicles. The cap of any of the illustrated embodiments of the present invention may comprise a dust cap 26, illustrated here as implemented with the embodiment of Figure 2B. However, a similar arrangement can be applied to the outlet apertures 25 of Figures 1 , 2A, 2C and is particularly advantageous if the container to which the cap is applied is intended to be arranged with a vertical configuration, since dust or other dirt is more likely to collect in the cap in such a configuration, with the aperture 25 pointing substantially upwards. The dust cap may be pivotally mounted within the outlet aperture. The pivotal mount may be located within the outlet aperture and may be arranged away from a pouring side of the aperture such that the dust cap can be opened by force of liquid exiting the aperture when pouring and is reclosed by gravity once pouring has stopped and the closure arrangement is rotated towards a vertical configuration in which the spout is substantially upwardly facing, which may be essentially any position in which an axis of the cap and the neck is angled above the horizontal.

Figure 2C illustrates an example where it may be desirable to reduce the diameter of the spout or of the chamber 24 with respect to the neck 11. The arrangement of Figure 2C has some similar features to those described in figures 1 to 2B, which are given the same reference numerals. The arrangement would be substantially symmetrical about the centre-line 201 , with the exception of threads 112 and 211 , since threads are not symmetrical in this way, but opposing corresponding features are provided to provide a functioning thread. The example of Figure 2C provides a closure portion 22 which may be a separate component. Closure portion 22 may further have a void 221 in the direction of lift 13 of the cap between a sealing edge 215 of the closure portion and the array of apertures. This can allow the array of apertures 23 to be located at a diameter of the cap 2 which is less than the diameter of the neck 1 1 or of its bore 12. The sealing edge 215 may therefore be located at a diameter greater than that of the array of apertures 23.

Figure 3 illustrates alternative configurations for creating a seal between closure portion 22 and end portion 1 13 of neck 11. The sealing arrangements may be used with any of the examples described in Figures 1 and 2A/2B and later described in this description.

A resilient seal 31 may be provided between an outer wall of neck 11 and an inner wall of cap 2. Seal 31 may be a nitrile seal or any other suitable resilient sealing means.

Additionally, or alternatively, resilient seal 32 may be provided on closure portion 22. Although not illustrated as such in Figure 3, this may be of a substantially O-ring shape such that when used, it would appear symmetrically on both sides of the closure portion 22 shown in Figure 3.

A further alternative would be to mould a resilient sealing feature 33 around an outer edge of closure portion 22. This would allow a degree of resilience in the sealing interface between closure portion 22 and end portion 113 of neck 11 without the need for additional components. If provided, this feature 33 would extend all around an edge of closure portion 22 and thus would appear on both sides of closure portion 22 as illustrated in Figure 3. Figure 3 therefore is asymmetrical in appearance in order to illustrate the alternative sealing means 32 and 33 which may be used.

Figure 4 shows a bottom view of a cap 2 for use in the present invention to illustrate features of the closure portion 22 and orifices 23. Orifices 23 are arranged in a substantially circular array adjacent the threaded portion 21 of the cap. The closure portion 22 is substantially solid in its central portion to provide a sealing function on end portion 1 and 3 of bore 12 of Figures 1 and 2. The apertures 23 are configured to provide the flow area substantially equal to that of a neck to which the cap can be applied. The cap has an inner diameter 41 substantially equal to the outer diameter of the neck 11. The apertures 23 are configured to have a width in a radial direction no greater than the thickness of the wall of the neck and, in particular, no greater than the width of an end portion abut against the apertures, or against the closure portion to one side of the array of apertures 23, and can therefore seal them against the passage of fluid.

In particular examples, a 25mm neck, having a bore diameter 41 of 25mm, will provide a 225mm ² flow area. This can be combined with an array of apertures, preferably 14 to 16 apertures, which are approximately 3mm wide in a radial direction of the cap and approximately 6mm long in a circumferential direction of the cap 2. This provides a total aperture flow area provided by apertures 23 of approximately 250 mm ² , which is greater than that provided by the bore 12 of the neck 1 1. In a further example, the neck may have a diameter 41 of 33mm, which provides a flow area through the bore 12 of the neck of 256 mm ² . For this configuration, an array of 16 3mm by 6mm apertures can provide sufficient flow area to be as great as that of the neck.

An important sealing feature can be that the chamfers 1 15 and 215 of Figure 1 meet in order to seal the apertures 23 from the bore 12 of the neck 1 1. The precise form of the end portion 1 13 may therefore not be important, so long as the champers 1 15 and 215 meet one another.

Figure 5 illustrates one type of container in which the present invention may be implemented. In the illustrated example, the cap 2 is formed as a spout. The spout 2 is attached, in threaded engagement, to the body 51 of the container 5 and may be rotated about its threaded portion 53 relative to the container. The spout 2 has a relatively elongate chamber extending from the threaded portion 53 of the spout 52 to the outlet orifice 55. The spout 52 of the container 5 may be equipped with all of the features of the example closure shown in Figures 1 and 2, or any sub-set of those features.

The closure arrangement of the container 5 may be configured such that the half turn of the spout 52 provides an equivalent flow area to the outlet orifice 55 as described above in relation to orifice 25 of the earlier figures. In this way, when the spout 52 is rotated into the position shown in Figure 6 the apertures 23 of the closure portion are open, to allow fluid to flow from the bore 12, and fluid may be poured from the container 5 through spout 52.

The thread of the container may be arranged such that further rotation of the spout 52, optionally through a ¾ turn or more from the closed position, releases the spout completely from the container. The container can thus be refilled through the bore of the neck. A problem which may be encountered when pouring liquid from a container such as that shown in Figures 5 and 6 can be that so-called "glugging" occurs, since air must enter the container through the spout 52 at the same time as liquid must escape through the spout 52, so that a volume of poured liquid can be replaced with air.

Figure 7 illustrates how an air vent may be provided in the body of the container 5, which is sealed when the spout 52 is in its closed position and is open to allow the passage of air when the spout 52 is in the open position, i.e. that illustrated in Figure 6. In the illustrated example, the distal end of the spout 52, adjacent outlet orifice 55, is provided with a projection 56. The body 51 of the container is provided a spout engagement portion 511 , which is configured to engage the distal end of the spout 52 when the spout is in its closed position. The engagement portion is provided with an air venting hole 57, which is optionally provided with a grommet 571 to aid in sealing the air vent 57 by engagement with the projection 56 of the spout. The spout engagement portion having the air vent opening is provided at an end of the container remote from the neck 11. The advantage of this location is that when liquid is poured from the neck 1 1 , air can enter the container at a higher point in the container, so liquid is less likely to escape through the air vent unintentionally. A one-way valve in the air vent could also prevent liquid inadvertently being lost through the air-vent when the spout is in its open position.

Spout retaining means 58 are provided. In the illustrated example, an extension is attached to spout engaging portion 511 of the container body 51. Spout retaining means 58 are provided in the form of an opening 581 and the spout is provided with a corresponding engaging feature 521 , which, when the spout is placed in its closed position, engages with opening 581 of spout retaining means 58. With the provision of such features, the spout 52 can be securely retained in its closed position, simultaneously sealing the air vent 57. The illustrated extension can be difficult to manufacture and so an alternative is to provide a feature similar to feature 521 on a side of the spout facing the body of the container and to provide a corresponding recess or sloped feature having a similar profile to feature 521 on the container body. This can provide the spout retaining means without a need for further additional moulded features such as the illustrated extension attached to the spout engaging portion 51 1. A further alternative spout retaining means can be a movable member attached to the body of the container or to the spout engaging portion. The movable member may be pivotable about a connection to the container. The retaining means may comprise biasing means for biasing at least a part of the retaining means toward an retaining position in which it engages and/or retains the spout. An additional feature when in the closed configuration, such as is illustrated in Figure 5, is that the spout 52 may act as a convenient handle for the user.

Accordingly, the spout 52 has multiple functions of, acting as a handle, providing a seal for the neck of the container and providing a spout through which water may be poured from the container when in an open position. As described above, when the threads are configured to allow sufficient flow area with a half turn and to release the spout when the spout is rotated more than a half turn from its pouring position, then the position provides a dual function of acting as a removable and recloseable closure for the neck of the container and also as a spout through which liquid may be poured. Secondary spout engagement means may be provided to secure the spout in its closed position. In Figure 7, this is provided by a protrusion 512 on the body. This is configured so that a tie may be passed around the spout 52 and subsequently around the protrusion 512 to secure the spout in the closed position.

Figure 8 illustrates the outline of the distal end of the spout 52 in greater detail, where the container is intended for use in automotive applications, the diameter 81 of a distal end of the spout may be 20 mm. This allows the spout to enter into a 21 mm filler port, such as is used for a standard European unleaded petrol vehicle. Engaging feature 521 is shown in more detail, although in mirror- image with regard to Figure 7. Engaging feature 581 has a first side which is substantially radial with respect to orifice 55 and a second side which is inclined with respect to the outer surface of the spout. This allows the spout to slide smoothly into its locked closed position by deforming feature 58 of Figure 7, which is then clicked back into place when the opening 581 reaches the substantially radially oriented side of 521.

Figure 9 illustrates a grommet 571 which may be used in the air vent 57 of Figure 7. The grommet 571 may be made from a resilient material such as rubber, nitrile, or another material having similar resilience and sealing properties such that when it engages with protrusion 56 of the spout, a seal is created between the bore 572 of the grommet and the outer surface of the protrusion 56 to prevent the passage of liquid through the air vent.

Figure 10 illustrates the spout 52 in a partially closed position, approaching its closed position, when the distal end 520 approaches engagement with the spout engaging portion 511 of the body 51 of container 5. As the spout 52 is advanced in a direction of arrow 100, the spout 52 engages with the spout engagement portion 51 1. The spout retaining means 58 and its opening 581 engage with the distal end 520 of the spout and the corresponding engaging portion 521 of the spout. Simultaneously, the protrusion 56 engages the air vent 57 to seal the air vent.

Figure 1 1 shows further details of a spout 52 which may be used with the container of Figure 5. Positive location means are provided in the form of two projections 59. These may be configured to engage with a projection on the body of the container 5, so that the spout 52 is retained positively in its open position by engagement of the bumps 59 with the projection on the body (not shown).

Where the spout is intended for use in an automated applications, the diameter 1100 of the spout at distances 1 101 of less than 10cm should be less than around 36mm. This allows the spout to sufficiently enter the fuel filler orifice of a vehicle an open any trap doors located in the filler port. An area of increased diameter 522 may be provided on the distal end 520 of the spout, between projection 56 and outlet orifice 55 of the spout, to prevent any orifice into which the spout is inserted from damaging projection 56.

Figure 12 shows a side view of the spout 52 and illustrates a further diameter increasing feature 523 which may be applied to the distal end 520 of the spout 52. In general, an unleaded petrol pump filler tube is 21 mm diameter while leaded petrol or diesel tubes are 25mm diameter, thereby preventing these latter 25mm tube from inadvertently being inserted in a filler of an unleaded petrol vehicle. The 24mm diameter tubes must not access into a petrol can or petrol car filler port, but could access a petrol or diesel aperture of larger diameter. There is therefore a need to be able to provide two versions of spout 52, one of which can enter into an unleaded petrol cap of a car or filler can, and another which cannot. By the provision of a diameter increasing feature such as 523 illustrated in Figure 12, different versions of the spout 52 be created with a minimum of retooling during the manufacturing process.

Figure 13 illustrates an alternative construction of the spout 52, in which the threaded portion 131 is formed separately from the elongate chamber portion 132 extending to orifice 133. Closure portion 22, including apertures 23 of the closure arrangement illustrated in Figures 1 and 2, is formed on threaded portion 131 of the spout assembly. When the two portions 131 and 132 are assembled together in the direction of arrow 134, the two parts can subsequently be welded together by spin welding or any other suitable fixing means as described above.

Figures 14A to 14D show an alternative arrangement for providing the function of locking the spout of the present invention in a closed position and simultaneously sealing an air hole in the container. The arrangement 14 comprises an up-stand, or raised portion 141 , arranged on a part of the container distal from the pouring opening, such that the raised portion 141 is substantially adjacent a closed position of the spout 142 when the spout is closed. Figure 14A shows the arrangement in a partially opened configuration.

Figure 14B shows an elevated view of the arrangement of Figure 14A with the spout 142 opened a little further towards the open configuration. An air hole 143 with an optional grommet inserted in the air hole 143 can be seen facing upwardly on the container, or in a direction of the spout.

As can be seen in Figure 14C, when the spout 142 is moved to a closed position, a distal end of the spout is arranged under a raised portion 141 of the container, which has a locking portion 144 which is arranged to engage the spout at a position opposite the main body of the container 145. In this arrangement, air hole 143 is sealed by the body of the spout 142. An optional bump or protrusion may be included in the underside of the body of the spout as shown in Figure 14C, so that it can at least partially enter the air hole 143 to provide an improved air seal when the spout is in the closed position. As illustrated in Figure 14D, a securing means such as a zip tie 146 will be included to secure the spout 142 to the locking portion 144 of the up stand or raised portion 141 of the container. The locking portion 144 may comprise securing means engagement portions 147, which may be recesses, holes or other suitable engagement means for helping to retain the securing means in position to secure the spout in the closed position. The spout may be further held in place by a frictional force between the locking portion 144 and the body of the spout 142. Further, as illustrated in Figure 14B, the spout may have an end profile 148 which is shaped and configured to engage the outer profile of the up stand 141 to further retain the spout 142 in the closed position.