| WO/2010/086285 | INHALER |
| JP09140793 | MEDICATOR |
| WO/2002/074375 | AEROSOL GENERATION USING STERILE MULTIPLE DOSE CONTAINERS |
SCHENNUM, Steven, Michael (15154 Eyre Circle, Plainfield, IL, 60544, US)
| Claims 1. An aerosol generator comprising a body, a mouthpiece on the body, and a delivery mechanism operable to deliver aerosol for inhalation by a consumer into the mouthpiece by turning the mouthpiece and body relative to one another. 2. A generator according to claim 1 wherein the body includes a mounting to receive a canister of pressurised liquid for forming the aerosol. 3. A generator according to claim 2 wherein the mounting is configured to receive a canister including a discharge tube depressible inwardly to open a valve therein to release liquid from the canister through the discharge tube, and further including a nozzle member to be driven inwardly of the body upon said turning of the mouthpiece and body relative to one another, for depressing the discharge tube inwardly of the canister to open the valve. 4. A generator according to claim 2 wherein the nozzle member is in threading engagement with the body, the nozzle member having an end to abut the discharge tube of the canister, the nozzle member being coupled to the mouthpiece to rotate axially when the mouthpiece is rotated relative to the body and also to slide axially relative to the mouthpiece so as to be driven against the discharge tube of the canister to open the valve in the canister and discharge fluid into the nozzle member. 5. A generator according to claim 4 wherein the nozzle member includes a radially extending peg engaged in a helical groove in the body member to provide said threading engagement. 6. A generator according to claim 4 wherein the nozzle member is coupled to the mouthpiece by a key which engages with an axial groove in the mouthpiece to allow rotation of the nozzle member with the mouthpiece and axial sliding movement. 7. A generator according to claim 4 wherein the nozzle member includes an orifice to form an aerosol from the fluid discharged from the canister. 8. A generator according to claim 2 including a housing to receive the canister, the housing being releasably attached to the body member. 9. A generator according to claim 1 wherein the body and the mouthpiece are generally cylindrical with a common axis. 10. A generator according to claim 2 and including the canister. 11. A generator according to claim 10 wherein the canister is generally cylindrical with a valve therein operable by an axially disposed discharge tube upon axial depression inwardly of the canister. 12. A generator according to claim 11 wherein the canister is arranged coaxially with the turning axis of the delivery mechanism. |
Field of the invention
This invention relates to a portable aerosol generator which may be hand held and used to deliver aerosol to the mouth of a consumer, for example, but not exclusively an aerosol containing nicotine.
Background
A nicotine dispensing aerosol device is disclosed in US 4,945,929, which simulates a smoking article such as a cigarette, without having to burn tobacco.
Summary of the invention
This invention provides an aerosol generator comprising a body, a mouthpiece on the body, and a delivery mechanism to deliver aerosol for a consumer into the mouthpiece by turning the mouthpiece and body relative to one another.
The body may include a mounting to receive a canister of pressurised fluid for forming the aerosol, which may include a discharge tube depressible inwardly to open a valve therein to release liquid from the canister through the discharge tube, A nozzle member may be configured to be driven, upon turning the mouthpiece and body relative to one another, to depress the discharge tube of the canister inwardly to open the valve.
The nozzle member can be in threading engagement with the body, and have an end to abut the discharge tube of the canister. The nozzle member can be coupled to the mouthpiece to rotate axially when the mouthpiece is rotated relative to the body and also to slide axially relative to the mouthpiece so as to be driven against the discharge tube of the canister to open the valve and discharge fluid from the canister into the nozzle member.
Radially extending pegs may be provided on the nozzle member that are engaged in a helical groove in the body member to provide the threading engagement of the body and nozzle member. The coupling of the nozzle member to the mouthpiece may comprise keys on the nozzle member which engage with axial grooves in the mouthpiece to allow rotation of the nozzle member by manual rotation of the mouthpiece and also axial sliding movement.
The nozzle member conveniently includes an orifice to form an aerosol from the fluid discharged from the canister. Brief description of the drawings
In order that the invention may be more fully understood, embodiments thereof will now be described by way of illustrative example with reference to the accompanying drawings in which:
Figure 1 is a schematic perspective view of an aerosol generator;
Figure 2 is a side view of the major components of the generator shown Figure 1 when disassembled;
Figure 3 is an exploded view of the generator;
Figures 4a and 4b are cross sectional views of the generator with the mouthpiece end twisted outwardly, corresponding to a rest position in which the production of aerosol is inhibited, and with the mouthpiece twisted inwardly to an operative, discharge position to generate the aerosol, respectively;
Figure 5 is a perspective view of the body member shown in Figure 4;
Figure 6 is a longitudinal sectional view of the body member shown in Figure 5;
Figure 7 is a schematic perspective view of the nozzle member shown in Figure 4; Figure 8 is a longitudinal section of the nozzle member illustrated in Figure 7;
Figure 9 is a schematic perspective view of the mouthpiece of the device from its distal end;
Figure 10 is a longitudinal sectional view of the mouthpiece illustrated in Figure 9; and
Figures 11 A, 11B and 11C are sections of the generator along the planes X-X', Y, Y' and Z-Z' illustrated in Figure 4a. Detailed description
Figure 1 is a perspective view of an aerosol generator. The device is generally cylindrical and designed to be held between the fingers of a consumer's hand to simulate a smoking article such as a cigarette. The generator delivers an aerosol to the mouth of a consumer that may contain nicotine to simulate the smoking of a cigarette. Arrows A, B indicate the direction to twist in order to actuate the device. The arrows can be embossed or printed on the device for example.
Figure 2 is a side view of the generator during the process of inserting or removing a canister. Canisters can be interchanged in the generator in order to replace empty canisters after use. The major components shown in Figure 2 include a cylindrical canister housing 1 that is closed at one end, a cylindrical canister 2 that contains the product to be dispensed, and a twist section 3 that contains a mechanism to dispense aerosol from the canister 2. The canister 2 fits into the canister housing 1 and the canister housing is then attached to the twist section 3 using a threaded engagement. Alternative forms of attachment such as snap fitting or bayonet style could also be used. Also the canister housing may be incorporated into the body permanently to provide a device that is discarded after the supply of liquid in the canister is exhausted.
The canister 2 contains a product to be dispensed together with a liquid propellant such as, but not limited to HFA 134a. The specific combination of product and propellant can be altered to yield different flavors and effects. The product may comprise a nicotine-containing liquid with or without additional flavourings and additives, so as to simulate a smoking article such as a cigarette, although it will be appreciated that other compositions may be provided within the canister.
Figure 3 is an exploded view of the generator showing the major components: the canister housing 1, canister 2, a body 4, nozzle member 5, and generally cylindrical mouthpiece 6 that is mounted for rotation on the body 4 to supply the aerosol to the mouth of a consumer. The overall look of the device is similar to the look of a filter cigarette where the mouthpiece 6 may correspond in appearance to the filter and the canister housing 1 may correspond visually to the tobacco rod of a conventional cigarette.
Figure 4a is a cross section view of the device in an inoperative condition or rest position and Figure 4b shows the nozzle in a discharge position for spraying aerosol into the mouthpiece 6. The canister 2 has a generally cylindrical body 7
dimensioned to fit within the housing 1 and includes an integral spring loaded valve
8 with a valve stem in the form of a discharge tube 9, which, when driven inwardly against the force of the spring opens the valve to deliver a metered dose of the liquid within the canister through valve inlet tube 10 into the discharge tube 9 to form an aerosol.
The canister housing 1 has a closed, distal end 11 and a threaded proximal end 12 that is threaded onto the distal end of the body member 4. The threaded
engagement between the canister housing 1 and the body 4 ensures that valve stem
9 of canister 2 is pressed firmly onto the nozzle member 5.
As shown in Figures 4a and 4b, the body member 4 is generally cylindrical with a threaded distal end 13 to engage with the threaded proximal end 12 of the housing 1. The body member 4 includes an axial, tubular passageway that receives the nozzle member 5 and includes a middle section 14 that has an interior thread for driving the nozzle member 5 axially upon rotation of the mouthpiece 6. The interior thread is referenced 15 in Figures 5 and 6, which illustrate the body member 4 in more detail.
As shown in Figures 4a and 4b, the nozzle member can be driven towards the canister 2 to open the valve 8 by pressing the discharge tube 9 inwardly against the force of an interior valve spring 16, by a twisting action, as will be explained in more detail hereinafter.
Referring to Figures 7 and 8, the nozzle member 5 includes a stepped bore 17 which receives the valve stem 9 of the canister 2. An orifice 18 of restricted diameter acts as a nozzle and creates an aerosol from the fluid dispensed from the canister 2. An outlet passageway 19 delivers the aerosol into the mouthpiece 6.
Pegs 20 extending radially outwardly of the nozzle member 5, engage in the thread 15 within the body member 4. Thus, on rotation of the nozzle member 5, it is moved axially in relation to the body member 4.
The nozzle member 5 also includes keys 21 that are received within axial slots 22 in the mouthpiece 6 as illustrated in Figured 9 and 10.
As shown in Figure 10, the mouthpiece 6 comprises a generally cylindrical body having a distal end with an enlarged bore region 23 with an interior, annular end channel 24 that can be push fitted onto annular ledge 25 on the body member 4 illustrated in Figure 5. Once fitted, the mouthpiece 6 can rotate axially relative to the body member 4. Referring to Figure 9, the mouthpiece 6 also includes axially extending ribs 26 which maintain the nozzle member 5 axially within the
mouthpiece. A stop 27 limits axial movement of the keys 21 in the slots 22.
In use, when the mouthpiece 6 is rotated clockwise when viewed from the mouth end, the nozzle member 5 is rotated axially due to the engagement between the keys 21 on the nozzle member 5 and the slots 22 in the mouthpiece. The pegs 20 are guided by the thread 15 within the body member 4 so that upon rotation of the mouthpiece 6, the nozzle is guided by the thread 15 to be driven inwardly, towards the canister 2, and as a result, the discharge tube 9 is driven inwardly towards the valve 8 of the canister due to the stepped bore 17 shown in Figure 8 being urged against the discharge tube 9.
As a result, the valve 8 is opened against the force of its interior spring 16 and a metered dose of fluid from within the canister 2 is ejected through the discharge tube that comprises the valve stem 9, into the nozzle member 5 to be formed into an aerosol as it passes through orifice 18 into the outlet tube 19. The outlet tube 19 leads into an enlarged outlet region 28 at the mouth or proximal end 29 of the device, for provision to a consumer. Thus, the consumer can dispense a metered dose of aerosol by twisting the body member 4 along with the canister housing 1 and canister 2 attached thereto, in a direction of arrow A relative to the mouthpiece 6, as illustrated in Figure 1. The resulting aerosol spray 30 is illustrated in Fig. 4b. It will be appreciated that after dispensation of the metered dose, the device is twisted in the direction of arrow B so that the process can be repeated. The rotation is limited by the keys 21 moving axially towards the mouth end 29 and abutting the stops 27. Also, spring 16 of the metered valve 8 assists in the return in the direction of arrow B.
The device may be actuated using two hands to grip the mouthpiece 6 and the canister housing 1 although it may be possible for the consumer to operate the device by holding the mouthpiece 6 between their lips and twisting the canister 1 in the direction of arrow A of Figure 1.
Various modifications and variations fall within the scope of the invention. For example, visual clues may be provided on the canister to allow it to be oriented when installed so that the inlet tube 10 dips downwardly in normal use so all of the contents of the canister 2 can be readily consumed. Also, an interior spring may be provided to bias the mouthpiece 6 to normally assume the position shown in Figure 4b, so that after a dose of aerosol has been dispensed, the device automatically assumes a configuration ready to dispense a further dose.
Furthermore, although the canister is described as an interchangeable element to allow the supply of liquid to be replenished, an integral pressurised supply vessel may be provided in the device, so that the device can be used multiple times and then discarded once the liquid supply has been exhausted from the vessel. In a modification, an inlet valve may be provided to allow the supply to be replenished from an exterior, pressurised source. The valve 8 described herein is configured to deliver a metered dose on actuation but instead, a continuous flow valve could be used such that the consumer can maintain a flow of aerosol by continuously holding the device in the discharge position, allowing the consumer to control the aerosol dose.
The mouth end can be configured differently from that shown in the Figures. For example the mouth end could be a tapered cylindrical shape with flat piece for easy positioning and orientation cue in the mouth. Also, textured or rough finishes can be applied to the exterior surface of the mouthpiece to stimulate sensation in the lips.
In addition, soft plastic moulding may be provided on the canister housing or mouthpiece to act as grip points for the consumer to use when twisting the device to the discharge position. This moulding may also possess a textured surface to provide different touch sensations.
The supply tube of the pressurised canister may be of flexible construction and provided with a weighted end as to always assume the lowest position in the canister orientation and allow for complete consumption of the canister contents.