This application is the U.S. national phase of International Application No. PCT/GB2011/000126, filed 1 Feb. 2011, which designated the U.S. and claims priority to GB Application No. 1001762.2, filed 3 Feb. 2010, the entire contents of each of which are hereby incorporated by reference.
The present invention relates to a dispensing container.
In this specification the term “gravitational torque” is used and its meaning is, in respect of a pivot axis or fulcrum and a gravitational attraction acting through a centre of gravity, the product as torque of the gravitational attraction and the horizontal spacing of the pivot axis or fulcrum and the centre of gravity.
The terms “attitude” and “orientation” are also used in respect of the disposition of a container on a flat surface:
“Attitude” means the container's general disposition, in particular either of its stood-on-end attitude or its lain-on-its-side attitude;
“Orientation” means its angle within its attitude, in particular its angle to the vertical or angle of tilt1 when in the stood-on-end attitude or the angle to which it rolls when in the lain-on-its-side attitude. 1 c.f. The leaning Tower of Pisa.
The term “cylinder” is used herein in its mathematical meaning, namely: “A surface generated by a line which moves parallel to a fixed line so as to cut a fixed plane curve”.2 2 Chambers Dictionary of Science and Technology
A cylinder can be “infectionless” when the plane curve has no changes in the sign of its curvature, in other words where it is convex throughout its extent. Alternatively, it can be “inflected” when the curve includes a change in curvature sign, i.e. it includes a concavity. The most common cylinder is a “right circular cylinder” in which the curve is a circle and the fixed line is at right angles to the plane of the circle. Purely by way of illustration, if the curve is an ellipse, the cylinder is an elliptical cylinder.
Metered dose inhalers use a container of the following type, “the type defined”, namely a pressurised liquid dispensing container comprising:
a valve for dispensing the liquid from the container; and
a vessel containing the liquid under pressure, the vessel having:
the vessel defining:
A problem with this type of pressurised liquid dispensing container is that normally the vessel is made of impact extruded aluminium or rolled and welded sheet steel; these materials are opaque. It is not possible to see the quantity of liquid in the container; nor can it be readily assessed by normal handling, feel nor sound.
Nevertheless there is a requirement for such assessment, particularly in the medical field.
The object of the present invention is to provide an improved pressurised liquid dispensing container.
According to the invention there is provided a pressurised liquid dispensing container of the type defined, the container having within the inflectionless cylindrical envelope:
Normally the cylindrical envelope will be a right circular cylindrical envelope, although for special purposes, other cylindrical envelopes can be envisaged.
Further the formation where provided within the envelope can be an inflection of the sidewall within the inflectionless cylindrical envelope. In which case sidewall may have an inflected cylindrical shape along at least part of its length. However in certain embodiments the formation is a shaped truncation of the vessel at its end wall, with the furthest extent of the end wall defining the end of the cylindrical envelope.
Normally the valve is of the type in which depression of a central stem of the container releases a metered dose. However this invention is not restricted to metered dose containers, but includes container of the type in which a continuous stream of liquid can be dispensed from the valve.
It is envisaged that the containers of the invention can have the formation-or-element arranged for estimation of their contents either when in the stood-on-end attitude or when in the lain-on-side attitude. We find the respective descriptions “bi-stable” and “roll-stable” to be useful. However, these are used hereinbelow only in respect of the specific embodiments, not least because we envisage that the stood-on-end attitude arrangement can in fact have more than two stable states.
In the stood-on-end attitude alternative:
In a simple embodiment of this alternative, the end wall of the vessel is angled with respect to a normal plane across the circular cylindrical envelope such that when the container is stood on end, it is tilted. The angle of tilt is such that the empty container tilts further. This angle may be 15° to 18°. It is more likely to between 18° and 25° or more, but is unlikely to be 30°.
Under 14°, the container is unlikely to fall over when empty, but can be induced to do so by addition of weight to the fulcrum side of the container.
The end wall can be plain at its angle, either flat or more likely indented; in either case the fulcrum point will be point of the end closest to the valve end of the vessel. Alternatively, the end wall can be ridged, both for grip and to provide a clearly defined fulcrum axis.
In another embodiment, the end of the wall is not angled with respect to the normal plane, but the end wall is formed with a fulcrum close to the central axis of the cylinder and a support, whereby the container can stand up right when full and stood on end. The end wall is formed with a punt between the fulcrum and the support, whereby when little liquid contents remains in the container, it is directed to occupy space in the vessel outside the fulcrum and cause the container to tip about the fulcrum.
Preferably the centre of gravity of the container per se is outside the fulcrum. Conveniently this can be arranged by adding weight to this side of the container. Alternatively the sidewall of the vessel at the end wall can be indented in the region of the support. This can have the effect of displacing the centre of gravity of the container per se eccentrically outside the fulcrum. The indent can also replace the punt. The centre of gravity can also be displaced be arranging the valve eccentrically of the cylinder of the vessel.
In an embodiment combining features of the above two embodiments, the fulcrum and the support tilt the container with its higher centre of gravity to fall outside the fulcrum, whereby it falls over when empty, yet the tilting is insufficient to cause the centre of gravity of the contained liquid to fall outside the fulcrum at least until the level of the punt is reached.
In either this or the preceding embodiment, the end wall outside the fulcrum can be formed to restrain the container from falling over completely from its stood-on-end attitude.
In the laid-on-side attitude alternative:
Whilst the buoyant formation-or-element must displace some liquid and hence displaces the centre of gravity of the contained liquid from its position in absence of the formation-or-element, it should be noted that the displacement is likely to be small. Further the degree of eccentricity of the centre of gravity is equally likely to be small in that it counters the small displacement of the centre of gravity of the contained liquid.
Preferably, where the buoyant formation-or-element is a formation it is an inflection in the sidewall of the vessel. Conveniently it is formed such as to cause the centre of gravity to be eccentric. For instance, where the formation is a constant wall thickness indent, the indent has a longer extent than the equivalent piece of vessel wall on the opposite side of the vessel. Thus the indented formation biases the centre of gravity eccentrically towards itself.
Alternatively, if the formation is formed by stretching a piece of the wall, its effect on the centre of gravity, due to inwards movement of material, will be to bias the centre of gravity away from itself. In this situation, additional mass may be added, either internally of the vessel or externally.
Conveniently the indent extends from the end wall to the valve end of the vessel, whereby it acts as a wall displacing liquid in front of itself and giving a readily appreciable indication of the level of the liquid in the container.
Where the formation-or-element is an added element, conveniently attached to the valve or at least attached in the container by means of the valve attachment, which is otherwise conventional, the element will normally provide both the buoyancy and the eccentricity of the container's centre of gravity.
To help understanding of the invention, various specific embodiments thereof will now be described by way of example and with reference to the accompanying drawings, in which:
Referring first to
The end wall of the container remote from the cap is formed with a deep eccentric punt 4 and a chamfer 5, defining, with a rim 6 between the sidewall of the container and the punt, a fulcrum 7. The fulcrum is such that with the container stood on a flat surface S, pushing horizontally on the spout from the punt side will tip the container over once the righting moment of the weight of the contents of the container is overcome. The centre of gravity 9 of the contents above the punt is to the punt side of the fulcrum. The centre of gravity 8 of the container is just on the side of the fulcrum opposite from the punt.
It will be noted that the portion of the contents below the top of the punt has a centre of gravity 10 on the other side of the fulcrum. Taking account of the masses centred at the centres 8,9,10 and the relative positions of these centres of gravity with respect to the fulcrum, albeit with the centre of gravity 9 perhaps lower on account of use than as shown in
Thus removal of the source from an inhaler or other applicator and its placing up-ended on a flat surface will indicate whether it has a useful amount of content of medicament and its propellant left inside or not. If it does the weight of the contents acting to the punt side of the fulcrum keeps the container upright, supported on the fulcrum and the stability support in the form of the rim 6. If not, i.e. if the container is empty or close to empty, the weight of the contents opposite the punt at a greater moment arm 12 is not counter-balanced by the greater weight of the contents above the punt albeit at a lesser moment arm 14. The container will not stand upright and it will fall over indicating that the container is empty or nearly empty.
Turning now to
The container just described is envisaged to be able to be made by deep pressing. An alternative container is shown in
The embodiment of
When the container is stood on a level surface S, it has an angle of tilt of 20° as drawn. The end wall 52 is plain and elliptical in its plane, the impact extruded vessel 55 of the container being right, circular cylindrical. One elliptical extreme of the end wall is at the extent 53 and the other is a fulcrum point 56. (It should be noted that although fulcra are normally wide to provide a pivot axis, the width between the sides of the ellipse provide lateral stability whereby it is the fulcrum point which provides stability against tipping). The length of the vessel, its diameter and the angle of tilt are all such that the centre of gravity 57 of the vessel as such is vertically, or nearly so, above the fulcrum point. The vessel carries not only the spout 54, but the associated valve etc. which are conventional and not shown. The result is that the centre of gravity 58 of container as such is outside the fulcrum. The liquid contents 59 do not reach up to the top of the vessel, even when full. To a first approximation the centre of gravity of the vessel and contents extending to the full height of the vessel are close if not coincident. Therefore the centre of gravity 59 of the contents falls inside the fulcrum and the design of the container can be fine tuned to arrange that the container is stable when full.
In more detail the centres 58,59 of gravity intersect the plane of the end wall when the latter is horizontal at points 581,591. The line between the points intersects the perimeter of the end wall at the fulcrum point 56. The gravitational torques of the two centres of gravity, that is to say the product of the masses notionally at the centres and their moment arms from the points 581,591 to the fulcrum point, must be such that the gravitational torque of the contents is larger for stability when the container is full. When some of the contents has been used, the gravitational torque of the contents increases as less of the contents is outside the fulcrum. In practice, the mass of the contents is decreasing but the moment arm is increasing. This effect continues (with successive estimations of content as liquid is dispensed) until the liquid is all inside the fulcrum. Its gravitational torque then decreases until, when there is none left, the over-turning torque of the container per se causes the container to fall over from its stood-on-end (albeit tilting) attitude to its lain-on-side attitude. The point of actual tipping will be when a small amount of liquid is left. Thus if the container stands on end the user knows that there is a quantity left with a reserve; if the container won't stand on end, the reserve is already being consumed.
Although the end wall is described above as flat in practice is likely to be slightly dished in to avoid it bowing out under the pressure of the contents as is conventional.
Referring to the drawings, in
Referring on to
The container 121 of
The embodiment of
Again the embodiment of
The invention is not intended to be restricted to the details of the above described embodiment. For instance, not only can the invention be used for metered dose medical inhalers, but it can also be used for general purpose aerosol dispensers. Further, it can be used for containers having metal vessels, in particular aluminium and steel vessels, as well as plastics materials vessels.
Number | Date | Country | Kind |
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1001762.2 | Feb 2010 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2011/000126 | 2/1/2011 | WO | 00 | 9/12/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/095761 | 8/11/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3505870 | Smylie | Apr 1970 | A |
3885698 | Lebel et al. | May 1975 | A |
4257558 | Mason, Jr. | Mar 1981 | A |
5579759 | Gantz | Dec 1996 | A |
5785048 | Koerner | Jul 1998 | A |
5860552 | Culhane et al. | Jan 1999 | A |
6581539 | Rasor | Jun 2003 | B1 |
7168433 | De LaForcade | Jan 2007 | B2 |
Number | Date | Country |
---|---|---|
2 736 331 | Jan 1997 | FR |
2 348 676 | Oct 2000 | GB |
WO 9807459 | Feb 1998 | WO |
Entry |
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International Search Report for PCT/GB2011/000126, mailed Jun. 21, 2011, (Daintith, Edward). |
Number | Date | Country | |
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20130001258 A1 | Jan 2013 | US |