The present invention is concerned with an actuator cap for a fluid container that allows the contents of the container to be sprayed without the cap having to be removed. The invention is of particular use in the field of home and personal care when it may be used as part of a hand held aerosol dispenser. A particular aspect of the invention is that the actuator enables the dispenser with which it is associated to be interchangeably converted between operative and inoperative states.
Sprays through actuator caps enabling conversion between operative and inoperative states, optionally for use with pressurised fluid containers, have been described in the prior art.
U.S. Pat. No. 4,542,837 (Metal Box) discloses an actuator having upper and lower rotatable parts which may be rotated between operative and inoperative positions.
EP 2,049,415 B1 (Valois) discloses a fluid dispensing head comprising actuator means for driving a pushbutton in axial displacement relative to the valve rod, the pushbutton being used to trigger dispensing.
It as an object of the present invention to provide a robust, yet ergonomically attractive dispensing means for spraying liquid products, particularly products intended for application to the surface of the human body.
The invention is particularly suitable for applying cosmetic products to the surface of the human body, especially to the underarm regions of the human body.
An actuator cap for dispensing a liquid product, comprising a rotatable outer body and an associated actuator button and a non-rotatable chassis and an associated spray channel assembly, the latter comprising an outlet nozzle; the outer body and actuator button being rotatable between:
In a second aspect of the present invention, there is provided a method for applying a cosmetic product to the surface of the human body comprising the use of an actuator cap according to the first aspect of the invention in combination with a supply of suitable cosmetic product.
The actuator cap of the present invention is designed for use with a supply of fluid product, particularly fluid cosmetic product for use on the surface of the human body. The fluid product is supplied from a container to which the actuator cap is attached.
The actuator cap is particularly suitable for use with a pressurised aerosol canister containing the product to be dispensed.
A key feature of the invention is the rising actuator button. When the actuator button is not raised, the device is incapable of operation, giving it a safe transit and storage position. This position is additionally safe because the actuator button itself is protected from damage in this position, being surrounded by the outer body. There are also advantages with regard to stacking devices incorporating the ‘closed’ actuator button and associated fluid container.
When the actuator button is raised, this gives a visible and tactile indication to the user that the device is ready for operation. It also has the psycho-ergonomic benefit that it is the part that has changed, i.e. raised, that needs to be pressed for the device to be actuated.
The actuator cap has the further advantage that it is easily returned to its non-operable state by rotating the outer body and actuator button in the direction opposite to that required to go from the aforementioned first position to the second and third positions.
In preferred embodiments, the outer body encloses the non-rotatable chassis and the associated spray channel assembly. In such embodiments, the spray channel assembly, typically the most fragile element of spray through caps, is always enclosed by the actuator cap and does not itself need to rise through the cap in preparation for actuation. Designs in which the spray channel assembly needs to rise significantly to achieve activation are prone to stresses that the actuator caps of the present invention avoid.
In preferred embodiments, rotation of the outer body in a first direction causes the actuator button, but not the spray channel assembly, to rise and rotate in this same direction, and rotation of the outer body in a second opposite direction causes the actuator button, but not the spray channel assembly, to fall and rotate in this same opposite direction.
In preferred embodiments, the actuator cap comprises means for driving rotation of the outer body towards completion. This can be to complete rotation to the primed position and/or rotation towards the fully closed position. This is typically achieved by means of leaf springs and/or rotational tension between non-circulation as described in more detail later.
Herein, orientation terms such as “horizontal/vertical” and “upper/lower” should be understood to refer to the actuator cap oriented in an upright manner as it would be on top of an upright aerosol can with which it is designed for use.
Herein, the “front” of the actuator cap refers to the face bearing the spray outlet; the “sides” are the faces orthogonal to this face and the “rear” is the face parallel to, but away from that bearing spray outlet. These terms have the same meaning (mutatis mutandis) when used with reference to components of the actuator cap and relate to the actuator cap in its “primed” position.
Herein, the actuator cap should be understood to be “primed”, i.e., ready for actuation, when the actuator button is in its raised and tilted position ready for depression.
The components of the actuator cap are typically made from plastic. The outer body and chassis may be made from polypropylene, as may the spray channel. The swirl chamber, if employed, is typically made using a spray insert preferably made from acetal.
The features described with reference to the following specific embodiment may be incorporated independently into the generic description given above and/or as given in the claims.
Also illustrated in
Also illustrated in
The outer edge of the chassis (5) at its lower end is defined by the collar (4). Immediately above the collar (4) there is a short peripheral skirt (34) of almost circular profile. This skirt (34) projects upwards from a horizontal peripheral ledge (35) which links the bottom of the peripheral skirt (34) to the top of the collar (4). When the actuator cap (1) is assembled, the lower edge of the outer body (2) sits upon the peripheral ledge (35). Interaction between the inner surface of the outer body (2), which has “rounded rectangular” cross-section and the outer surface of the peripheral skirt (34), which has an almost but not quite circular profile (see
There are two slots (40) between the platform (7) and the peripheral ledge (35). These slots (40) comprise gaps existing in both vertical and horizontal planes. The vertical gap is constant across the full dimensions of the components, the platform (7) being held at the same height above the surrounding peripheral ledge (35) across all its extent. The radial gap between the platform (7) and the ledge (35) varies radially, decreasing steadily in width in a clockwise direction starting from the points adjacent to the clockwise edges of the wider connecting ribs (9). This may most clearly be seen in
The location of the leaf springs (24) is such that their lower ends sit outside the sections of the low wall (12B) nearest to the centre of the chassis (5) when the actuator cap (1) is in its fully open or fully closed position; hence, the leaf springs serve to drive the outer body (2) towards these rotational positions when close thereto.
The chassis has a central aperture (26) into which the spray channel assembly (6) is designed to fit snugly. The aperture (26) is roughly circular in cross-section, but has distinct narrowed sections (27) that interact with narrowed sections on the body (28) (see
One of the two leaf springs (24) is part illustrated in
During the manufacture of the dispensing cap (1), the retaining clips (39) are pushed through the slots (40) in the chassis (5) where the latter have their maximum radial width (vide supra), this easing manufacture. This corresponds to a radial positioning of the outer body (2) relative to the chassis (5) as present when the actuator cap is in its primed position. Following insertion, the retaining clips (39) are rotated in the slots (40) in the chassis (5) to the position where the latter have their minimum radial width, this corresponding to a radial positioning of the outer body (2) relative to the chassis (5) as present when the actuator cap is in its fully closed position. This serves to provide a high strength link between the outer body (2) and the chassis (5) when it is most needed, the consumer typically receiving the actuator cap (1) in a fully closed condition, together with an associated aerosol can, and proceeding to mistakenly attempt to pull off the actuator cap (1), believing it to be a conventional over-cap.
The retaining clips (39) are each strengthened by three support struts (45) that project downwards from their lower surfaces and brace against the inside of the skirt (17) at its front and rear. Two of the support struts (45) for the retaining clips (39) are located at the edges of the retaining clips (39) and project upwards as well as downwards. These edge support struts (45) also serve as rotational stops when they come up against an the edges of the wider connecting ribs (9) that define the edge of the slots (40) in the chassis (5) into which the retaining clips (39) are designed to fit. The retaining clip support struts (45) are chamfered on their lower edges to ease insertion of the clips (39) into the slots (40) in the chassis (5).
The downward projections (37) from the middle of both parallel edges of the cut-away segment of the upper surface (25) are strengthened by orthogonal walls (46) that project outwards from their rear edges. These orthogonal walls (46) also help to guide the actuator button (3) in its movement within the actuator cap (1) (vide infra).
The front segment of the upper surface (25) of the outer body (2) is reinforced on its inner side by four support ribs (47) running in parallel from front to back.
The side walls (51) of the actuator button (3) bearing the pinions (49) are actually located towards the front and rear of the actuator cap (1) when it is in its fully closed position; however, anticlockwise rotation of the upper body (2) and associated actuator button (3) through 90° puts the device in its fully open or primed position, in which position the pinions (49) are located towards the sides of the actuator cap (1) as a whole. During the aforementioned rotation, the pinions (49) move up the channels existing between the downward projections (37 and 38) from the middle and rear (respectively) of the parallel edges of the cut-away segment of the upper surface (25) of the outer body (2), guided in part by the orthogonal walls (46) projecting outwards from the rear edges of the middle projections (37), and when fully elevated, sit in the concave depressions or yokes (43) at the top of said channels. In this latter position, the final anticlockwise rotation of the upper body (2) and associated actuator button (3) causes the actuator button (3) to pivot about an axis through the through its pinions (49), resulting in the actuator button (1) becoming raised at its front edge (vide infra).
Key components of the actuator button (3) shown in
The drive lugs (20 and 21) are of the same dimensions and face one another in the same front-back plane; however, the front drive lug (20) is located somewhat lower in the actuator button (3) than the rear drive lug (21). The front drive lug (20) sits on the longer drive ramp (18) of the chassis (5) and the rear drive lug (21) sits on the shorter drive ramp (10) of the chassis (5). When the actuator cap (1) is in its fully closed position, the actuator button (3) is level with the top wall (25) of the outer body (2) because the height difference between the front drive lug (20) and the rear drive lug (21) equates to the height difference at which the longer drive ramp (18) and the shorter drive ramp (10) commence. As anticlockwise rotation of the outer body (2) and associated the actuator button (3) commences, the actuator button (3) rises without slanting because the drive ramps (18 and 10) upon which the drive lugs (20 and 21) sit have the same slope. When the rear drive lug (21) reaches the horizontal section (19) of the shorter drive ramp (10), it does not rise further, unlike the front drive lug (20) which continues to rise further along the longer drive ramp (18), thereby producing a tilt in the actuator button (3), it being raised at the front at this rotational position.
When the drive lugs (20 and 21) have passed just beyond the end of their corresponding drive ramps (18 and 10), further anticlockwise rotation is prevented by the retaining clips (39) abutting the edges of the wider connecting ribs (9) spanning the slots (40) in the chassis (5). In this position, the actuator cap (1) is primed and the actuator button (3) may be depressed. The drive lugs (20 and 21) serve a second but equally important function during actuation. Having passed beyond the vertical edges (36) at the anticlockwise ends of their drive ramps (18 and 10), they are not blocked from depression. Downward force on the actuator button (3) causes the drive lugs (20 and 21) to press down upon the spray channel assembly (6) and this leads to actuation and release of product through the spray channel assembly (6).
If the actuation button (3) were to be pressed centrally, depression would in theory occur in a balanced fore and aft manner, each of the drive lugs (20 and 21) bearing down on the actuation spray assembly (6) and thereby avoiding possible lateral stress on the valve stem associated with the spray channel assembly (6) (vide infra).
In reality, the consumer tends to press the actuator button (3) more towards its rear, behind the axis of the pinions (49). This causes the actuator button (3) to pivot on its front edge and for pressure to be applied to the spray channel assembly (6) through the rear drive lug (21) rather than the front drive lug (20). This leads to distinct mechanical advantage because pressure is brought to bear on the spray channel assembly (6) closer to the pivot point than where it is applied. Indeed, it has been found that operation of actuator cap (1) in this manner can lead to an up to 1.6 times mechanical advantage. Fortunately, this “uneven” pressure application upon the spray channel assembly (6) is not transferred to the valve stem with which it is in use associated because the spray channel assembly (6) is held snugly in the aperture (26) in the intervening chassis (5).
Other components of the actuator button (3) are as follows. There is a rear wall (54) that is designed to fill the cut-away section in the upper rear part of the skirt (17) facing the aperture (16). There is a front wall (55). The downwardly projecting front plate (52) is a partial continuation of this front wall (55). The is a platform (56) extending forward from the front wall (55) and also outwards front the side walls (51) as flexible wing structures (57) which slope upwards as they extend outwards. The platform (56) and associated flexible wing structures (57) are designed to fit under the top wall (25) of the outer body (2) and the front-back angle of these features is such that they are in the same plane as the top wall (25) of the outer body (2) when the actuator button (3) is fully tilted and the actuator cap (1) is primed. In this position, the platform (56) and associated flexible wing structures (57) are pressed against the under surface of the top wall (25) of the outer body (2), flattening out the upward slope of the flexible wing structures (57).
In addition, the actuator button (3) has multiple (six) outward projecting strengthening ribs (58) on the upper surface of the part of the platform (56) extending forward from the front wall (55). The downwardly projecting front plate (52) has two support wedges (59) between it and the lower side of the platform (56) extending forward from the front wall (55). The internal cross-wall (53) has support ribs (60) projecting fore and aft. The side walls (51) each have a thin, outward-projecting, vertical rib (61) located just to the rear of the pinions (49). These ribs (61) lightly contact the inner faces of the downward projections (38) from the parallel edges of the segment cut-away from the top wall (25) of the outer body (2) and help to prevent undesirable sideways roll of the actuator button (3) when it is depressed.
From the underside of the spray channel assembly (6) in the centre there protrudes a tubular stem socket (68), designed to accommodate the valve stem of an associated aerosol container. The stem socket (68) is in fluid communication with the spray orifice (63) through the spray chamber (64) and other internal channels not illustrated but common in the art.
From the outer surface of the main body (28) at its lower end, two retaining clips (69) protrude from the “non-narrowed” or wider segments (28B) of the main body (28), on opposite sides of said main body (28). These retaining clips (69) fit underneath the corresponding retaining clips (33) that protrude into the central aperture (26) of the chassis (5) (vide supra) and help to hold the spray channel assembly (6) and the chassis (5) together.
There are two return ramps (11 and 65) of the same slope curving around opposite outside surfaces of the main body (28). These return ramps (11 and 65) sit above the drive lugs (21 and 20, respectively) projecting inwards from the actuator button (3) and serve to force the actuator button (3) downwards when the outer body (2) is rotated clockwise. The return ramp (65) to the left of the spray orifice (63) is longer than the return ramp (11) to the right of the spray orifice (63), viewing the actuator cap (1) from the front. The length of the longer return ramp (65) corresponds to the length of the longer drive ramp (18) and the front (lower) drive lug (20) sits between these ramps. The length of the shorter return ramp (11) corresponds to the length of the shorter drive ramp (10) and the rear (higher) drive lug (20) sits between these ramps.
The return ramps (11 and 65) have flat sections (66 and 67) at their upper and lower ends (respectively). The gap between the lower flat sections (67) and the flat sections (10A and 18A) leading into the corresponding drive ramps (10 and 18) on the chassis (5) is slightly less than the height of the drive lugs (21 and 20) that is forced between them as the outer body (2) is rotated to its fully clockwise position. As the chassis (5) is in fixed axial position, this causes an upward force on the spray channel assembly (6), resulting in a slight lifting of the stem socket (68) from the valve stem (not illustrated) with which it is associated in use, creating a “safety gap” when the actuator is in its closed position.
Number | Date | Country | Kind |
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11188489 | Nov 2011 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2012/069950 | 10/9/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/068189 | 5/16/2013 | WO | A |
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20150232258 A1 | Aug 2015 | US |