Flight Safe Mode For Aerosol Inhaler

Abstract

An electronic cigarette includes a mouthpiece portion having a refillable liquid store having a sealable opening, a valve closing member and an atomizer receiving section. The valve closing member is configured to seal the opening and control a flow of liquid from the liquid store to the atomizer receiving section. The flow of liquid to an atomizer is enabled when an atomizer is present in the atomizer receiving section. The atomizer is connectable to an inner sleeve at the atomizer seating in a power supply portion. The atomizer is moveable toward the valve closing member such that the valve closing member is urged toward the open position, and away from the valve closing member such that the valve closing member cannot be urged toward the open position, by axially moving the inner sleeve in relation to an outer sleeve with an actuator.

Claims

1. An electronic cigarette, comprising: a mouthpiece portion connectable to a power supply portion of an electronic cigarette, wherein the mouthpiece portion comprises a refillable liquid store having a sealable opening, a valve closing member and an atomizer-receiving section, wherein the valve closing member is configured to seal the opening and control a flow of liquid from the liquid store to the atomizer-receiving section by movement between an open position and a closed position, whereby a flow of liquid is enabled from the refillable liquid store to an atomizer in the atomizer-receiving section when an atomizer is present in the atomizer-receiving section and when the valve closing is moved towards the open position; a power supply portion with an atomizer seating configured to receive a lower portion of an atomizer, whereby the atomizer-receiving section in the mouthpiece portion is configured to receive an upper portion of an atomizer, wherein an inner sleeve at the atomizer seating is connectable to an atomizer, and wherein the inner sleeve is axially moveable in relation to an outer sleeve; an actuator configured to axially move an atomizer away from the valve closing member into a portion of the power supply portion such that the valve closing member seals the opening; and wherein the valve closing member can be urged toward the open position by the upper portion of the atomizer in the atomizer seating.

2. The electronic cigarette of claim 1, wherein: axially moving the inner sleeve in relation to the outer sleeve moves an atomizer toward the valve closing member to urge the valve toward the open position; and axially moving the inner sleeve in a retracting direction in relation to the outer sleeve moves an atomizer away from the valve closing member such that the valve closing member cannot be urged toward the open position.

3. The electronic cigarette of claim 2, wherein a portion of the actuator is comprised in the outer sleeve, and wherein the electronic cigarette further comprises a guiding arrangement configured to provide axial movement of the inner sleeve.

4. The electronic cigarette of claim 3, wherein the guiding arrangement comprises a guiding thread or groove wherein the inner sleeve is coupled to the guiding thread or groove through a follower pin, whereby the inner sleeve is movable in an axial direction when the portion of the actuator comprised in the outer sleeve is actuated.

5. The electronic cigarette of claim 3, wherein the inner sleeve is connected to the portion of the actuator comprised in the outer sleeve, wherein the portion of the actuator is an axially moveable actuator for direct axial movement of the inner sleeve in relation to the outer sleeve.

6. The electronic cigarette of claim 1, wherein the inner sleeve comprises resilient clasps and the outer sleeve comprises slots defined by bulges extending radially inwards, wherein the electronic cigarette further comprises an atomizer including a first engagement element in the form of an annular groove, and wherein the clasps are configured to connect to the annular groove and move within the slots to axially displace the atomizer.

7. The electronic cigarette according to claim 6, wherein the atomizer further comprises a first angled surface defining a lower ledge of the annular groove configured to enable the clasps to move into the annular groove, over the first angled surface, when the atomizer is pressed against the inner sleeve.

8. The electronic cigarette of claim 7, wherein the atomizer further comprises a second angled surface defining an upper ledge of the annular groove configured to abut the bulges when the inner sleeve is retracted in relation to the outer sleeve thereby releasing the atomizer from the clasps of the inner sleeve.

9. The electronic cigarette of claim 5, wherein the axially moveable actuator is a sliding actuator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0057] Embodiments of the invention are now described, by way of example, with reference to the drawings, in which:

[0058] FIGS. 1a and 1b show electronic cigarettes according to embodiments of the present invention.

[0059] FIG. 1c shows an exploded view of an electronic cigarette according to embodiments of the invention.

[0060] FIG. 2a shows a diagram of a mouthpiece according to an embodiment of the present invention.

[0061] FIGS. 2b and 2c shows a cross-sectional diagram of a mouthpiece according to an embodiment of the present invention.

[0062] FIG. 2d shows a cross-sectional diagram of a mouthpiece according to an alternate embodiment to that of FIG. 2b.

[0063] FIG. 3a shows a diagram of a mouthpiece according to an embodiment of the present invention.

[0064] FIG. 3b shows a cross-sectional diagram of a mouthpiece according to an embodiment of the present invention.

[0065] FIG. 4a shows a diagram of an atomizer according to an embodiment of the present invention.

[0066] FIG. 4b shows a cross-sectional diagram of an atomizer according to an embodiment of the present invention.

[0067] FIG. 5a shows diagrams of an atomizer being received in a power supply portion of an electronic cigarette according to an embodiment of the present invention.

[0068] FIG. 5b shows cross-sectional diagrams of an atomizer being received in a power supply portion of an electronic cigarette according to an embodiment of the present invention.

[0069] FIG. 6a shows a diagram of an electronic cigarette with a closed valve according to an embodiment of the present invention.

[0070] FIG. 6b shows a diagram of an electronic cigarette with an open valve according to an embodiment of the present invention.

[0071] FIG. 7a shows a diagram of an atomizer seating with an atomizer lock according to an embodiment of the present invention.

[0072] FIGS. 7b and 7c show cross-sectional diagrams of an atomizer seating with an atomizer lock according to an embodiment of the present invention.

[0073] FIG. 7d shows a partially transparent diagram of an atomizer seating with an atomizer lock according to an embodiment of the present invention.

[0074] FIGS. 8a-8c show cross-sectional diagrams of a leakage prevention system according to an embodiment of the present invention.

[0075] FIGS. 9a-9c show diagrams a leakage prevention system according to an embodiment of the present invention.

[0076] FIGS. 10a and 10b show diagrams of a refilling bottle according to an embodiment of the present invention.

[0077] FIG. 10c is a cross-sectional view of a refilling bottle in an embodiment of the present invention.

[0078] FIG. 10d shows an exploded view of a refilling bottle according to an embodiment of the present invention.

[0079] FIG. 11a shows a cross-sectional diagram of the interaction between a refilling bottle and mouthpiece portion of an electronic cigarette according to an embodiment of the present invention in which a liquid store of the mouthpiece portion and a liquid tank of the refilling bottle are both closed.

[0080] FIG. 11b shows a cross-sectional diagram of the interaction between a refilling bottle and mouthpiece portion of an electronic cigarette according to an embodiment of the present invention in which a liquid store of the mouthpiece portion and a liquid tank of the refilling bottle are both closed.

[0081] FIG. 11c shows a cross-sectional diagram of the interaction between a refilling bottle and mouthpiece portion of an electronic cigarette according to an embodiment of the present invention in which a liquid store of the mouthpiece portion is open and a liquid tank of the refilling bottle is closed.

[0082] FIG. 11d shows a cross-sectional diagram of the interaction between a refilling bottle and mouthpiece portion of an electronic cigarette according to an embodiment of the present invention in which a liquid store of the mouthpiece portion and a liquid tank of the refilling bottle are both open.

[0083] FIG. 12a is an exploded view of an electronic cigarette in an embodiment of the present invention.

[0084] FIG. 12b is a perspective view of the electronic cigarette shown in FIG. 12a, when assembled.

[0085] FIG. 12c is a detailed perspective view of the electronic cigarette shown in FIG. 12b showing the atomiser and a guiding arrangement.

DETAILED DESCRIPTION

[0086] Referring to FIGS. 1a to 1c, an electronic cigarette 2 according to embodiments of the present invention is illustrated. The electronic cigarette 2 comprises mouthpiece portion 4, a power supply portion 6 and an atomizer 12 which are releasably connected to each other.

[0087] The power supply portion 6 is provided as an elongate body having a proximal end 62 connectable to the mouthpiece portion 4 and an opposite distal end 64, a power supply unit or battery and an electrical circuitry (not shown). The distal end 64 may be provided with a charging socket in order to recharge the power supply unit. The electrical circuitry may include a control unit, a memory and sensor. The electrical circuitry is configured to control the operation of the electronic cigarette 2 such as to control the activation of the vaporization and any displayed features and communication to the user. As best seen in FIGS. 5a and 5b, the proximal end 62 further comprises an atomizer seating 66 configured to receive the atomizer 12 and electrically connect the atomizer 12 to the battery.

[0088] As illustrated in FIGS. 2a, 2b, 2c, 2d, 3a and 3b, the mouthpiece portion 4 comprises a refillable liquid store 10, a mouthpiece 8 and a vapour flow tube 32 and a valve 40. The vapour flow tube 32 provides a vapour flow channel 400 which extends between an atomizer receiving portion 67 and a vapour outlet 9 in the mouthpiece 8. The mouthpiece portion 4 is provided with a connection portion 50. The connection portion 50 is configured to securely connect with a cooperating connection on the proximal end 62 of the power supply portion 6. The connection portion 50 is located at an opposite distal end of the mouthpiece portion 4 to the mouthpiece 8. As seen in FIGS. 2a and 2b, the mouthpiece portion 8 can have a fixed mouthpiece portion 8a and a movable mouthpiece portion 8b. The movable mouthpiece portion 8b can be connected to the vapour flow tube 30 which is also movable. However, in preferred embodiments illustrated in e.g. FIGS. 3a and 3b, the mouthpiece portion 8 is fixed. A fixed mouthpiece portion reduces the risk of debris building up between a movable portion and a fixed portion and is also more comfortable for the user. The vapour flow tube 32 further comprises an abutment surface 32a, which enables the mouthpiece to eject an atomizer 12 when received in the atomizer receiving portion 67.

[0089] The liquid store 10 comprises a housing 11 having a top surface S1 and a bottom surface S2 located inside the liquid store 10. The top and the bottom surfaces S1, S2 may be arranged in transverse to the longitudinal extension of the electronic cigarette 2. The liquid store 10 is fluidically connected with the atomizer 12 via a liquid opening 7 in the bottom surface S2. The atomizer-receiving portion 67 is located at the connection portion 50 and configured to receive the top portion 12a of the atomizer 12.

[0090] In order to avoid free flow of liquid through the liquid opening 7 when the mouthpiece portion 4 is disconnected from the power supply portion 6, a valve 40 is provided inside the liquid store 10. The valve 40 comprises a valve closing member 44, a biasing member 42 and a sealing surface 43. The sealing surface 43 can be provided on the bottom surface S2 of the liquid store 10. The biasing member 42 is configured to bias the closing member 44 into a closed position in order to close the liquid opening 7 in the bottom surface S2 of the liquid store 10.

[0091] As seen in FIGS. 1a to 3b, the closing member 44 can be a sleeve 44, which is located around and guided by the vapour tube 32. A sealing member 34 may be positioned between the closing member 44 and the vapour flow tube 32. The sealing member 34 prevents liquid from entering the vapour flow tube 32. The closing member 44 has an axial length that is shorter than the distance between the top surface S1 and the bottom surface S2 of the liquid store 10. The closing member 44 is thus configured to move in the axial direction of the liquid store 10 between an open position and a closed position, i.e. in the direction of the longitudinal extension of the electronic cigarette.

[0092] The closing member 44 is provided with a horizontal flange 47 (i.e. perpendicular to the direction of the longitudinal extension of the electronic cigarette) with a diameter larger than the liquid opening 7. The biasing member 42 is encircling the closing member 44. The biasing member 42 has a first end in contact with the horizontal flange 47 and a second end in contact (i.e. biased against) the top surface S1 of the liquid store 10. The biasing member 42 is advantageously a compression spring 44. Alternatively, any biasing member 42 that provides a biasing effect can be used, such as a piece of resilient or elastic material.

[0093] The horizontal flange 47 of the valve closing member 44 can optionally be further provided with an elastic seal 46. The elastic seal 46 is fixedly connected to the horizontal flange 47 such that the seal 46 is substantially arranged between the horizontal flange 47 and the bottom surface S2 of the liquid store 10. The seal 46 is configured to both seal against the sealing surface 43 and an upper portion of the atomizer 12. The elastic seal 46 and the flange 47 may be attached to each other by a friction fit and or by cooperating geometries.

[0094] As illustrated in FIG. 2d, in an alternative embodiment, the closing member 44 can be guided along an inner side of the liquid store. In this case, the flange 47 extends inwardly and seals the liquid opening 7 in the bottom surface of the liquid store 10. The region of the flange 47 not aligned with the liquid opening 7 preferably comprises a liquid permeable portion so as to relieve the pressure created below the flange 47 as it moves downward compressing the liquid in the bottom portion of the liquid store 10. This allows liquid in the bottom portion of the liquid store 10 to be displaced upwardly as the valve closing member 44 moves downward.

[0095] As best seen in FIGS. 4a and 4b, the atomizer 12 may comprise a vaporization chamber 18, a heating element 20 and a fluid transfer element 22 located inside the vaporization chamber 18. The heating element 20 is not limited to any particular type. In the illustrated embodiment, the heating element 20 can be a resistive heating coil 20 comprising e.g. titanium. The heating element 20 can be arranged with its central aperture coinciding with the axial direction of the electronic cigarette 2, i.e. configured as a so called “vertical coil”. The vertical coil is advantageous as it fits with the cylindrical shape of the atomizer so as to form a compact atomizer 12. However, a horizontal coil arrangement can also be used.

[0096] As best seen in FIGS. 4a, 4b and 5a, the atomizer 12 is provided with a valve engaging portion 12a configured to be received into the atomizer-receiving portion 67 in the mouthpiece portion 4 and a seating portion 12b configured to be received in the atomizer seating 66 in the power supply portion 6. The valve-engaging portion 12a has an axial length exceeding the axial length of the atomizer-receiving portion 67. Hence, the valve-engaging portion 12a of the atomizer 12 partially extends into the liquid store 10 when the mouthpiece portion 4, the atomizer 12 and the power supply portion 6 are assembled together.

[0097] When the atomizer 12 partially extends into the liquid store 10, the valve closing member 44 is released from the sealing surface 43 and positioned at a location further upwards in the axial direction of the mouthpiece portion 4 such that the liquid opening 7 is opened. This opens a liquid communication from the liquid store 10 to the atomizer 12, as shown in FIG. 2c. It is noted that the atomizer itself is not shown in FIG. 2c, but the valve closing member 44 is displaced vertically in the mouthpiece portion as if an atomizer is present in the atomizer-receiving portion 67.

[0098] As illustrated in FIG. 3b, the closing member 44 may further comprise a connector 49 configured to sealingly connect the vapour flow tube 32 to the closing member 44. The connector 49 is placed at a distance from a connection end 51 of the vapour flow tube 32. When the atomizer 12 is located inside the atomizer receiving portion 67, the connector 49 abuts against the connection end 51 of the vapour flow tube 32 creating the vapour flow channel 400 between the atomizer and the mouthpiece 8. The connector 49 may advantageously be integrally formed with the seal 46. The connector 49 may also be funnel-shaped such that is surrounds a tapered connection end 51 of the vapour flow tube 40. In this way, the tapered connection end 51 of the vapour flow tube 40 extends into the connector 49 such that a sealed connection is achieved between the vaporisation chamber 18 and the vapour outlet 9.

[0099] The atomizer 12 comprises at least one liquid inlet 24 arranged in the proximity of the fluid transfer element 22. Preferably, a plurality of liquid inlets 24 are provided and arranged around the circumference of the atomizer 12. The liquid inlet or inlets 24 are arranged in the atomizer 12 such that when the atomizer 12 partially extends into the liquid store 10 the liquid inlet or inlets 24 are inside the liquid store 10. At least one air inlet 26 is located in the bottom portion of the atomizer 12. The air inlet 26 can be configured as an aperture. Alternatively, the air inlet 26 can be achieved by a clearance or gap in the bottom portion of the vaporization chamber 18.

[0100] As illustrated in FIGS. 6a and 6b, the valve 40 in the liquid store 10 can be opened when an object is applying a force and displacing the valve closing member 44 upwards in the axial direction of towards the mouthpiece 8. As seen in FIG. 6a, the valve 40 is closed when the power supply portion 6 is disconnected from the mouthpiece portion 4. As seen in FIG. 6b, the valve 40 is opened when the power supply portion 6 with the atomizer attached is attached to the mouthpiece portion 4.

[0101] The atomizer 12 is configured to be fixedly connectable to an atomizer seating 66 in the power supply portion 6. This provides an advantage that the atomizer 12 can be reliably electrically connected to the battery. Additionally, it is advantageous if the atomizer 12 stays connected to the power supply portion 6 and does not fall out if the mouthpiece portion 4 is disconnected from the power supply portion 6.

[0102] In an embodiment, the atomizer 12 is configured to be locked to the atomizer seating 66 by a relative rotation between the power supply portion 6 and the atomizer 12. As illustrated in FIGS. 7a to 7c, the atomizer seating 66 in the power supply portion 6 may therefore comprise an atomizer lock 120. The atomizer lock 120 comprises an outer sleeve 124 and an inner sleeve 122 which are rotatable in relation to each other. The outer sleeve 124 comprises a first protrusion 126 extending inwardly in the radial direction of the atomizer seating 66. The inner sleeve 122 comprises a second protrusion 128 extending inwardly in the radial direction of the atomizer seating 66.

[0103] Referring to FIGS. 4a, 7b and 7c, the atomizer 12 is provided with an engagement element 21 in the form of an annular ridge 21. The annular ridge 21 is only partially encircling the atomizer 12. This can be done by the ridge not performing a complete circle, or by a cut-out 23 in the annular ridge 21.

[0104] The atomizer lock 120 can be changed between a receiving position as illustrated in FIG. 7b and a locked position as illustrated in FIG. 7c. In the receiving position, the atomizer 12 can be inserted and removed from the atomizer seating 66 by an axial movement. This is possible because the first 126 and the second protrusions 128 are aligned with each other so as to form a “guide rail” in the axial direction of the atomizer seating 66. The atomizer 12 can therefore be introduced into the atomizer seating 66 by aligning the cut-out 23 in the annular ridge 21 with the first 126 and second protrusions 128.

[0105] The inner sleeve 122 further comprises a support surface 123 positioned such that the annular ridge 21 of the atomizer can rest against the support surface 123. The support surface 123 is thus configured to position the atomizer 12 at a correct depth in the atomizer seating 66.

[0106] In the locked position, as shown in FIG. 7c, as a consequence of the inner sleeve 122 and outer sleeve 124 having been rotated with respect to one another, the first protrusion 126 and second protrusion 128 are brought out of alignment with one another. The first protrusion 126 can therefore be arranged above the annular ridge 21 of the atomizer 12 when it is located in the atomizer seating 66, thereby locking the atomizer 12 in the atomizer seating 66. By rotating the first protrusion 126 and second protrusion 128 back into alignment the protrusions 126, 128 can pass through the cut-out 23 of the annular ridge thereby unlocking and releasing the atomizer 12 from the atomizer seating.

[0107] The inner sleeve 122 may further comprise a pair of resilient tongues 129a, 129b. The tongues 129a, 129b are biased radially outwards in the radial direction of the atomizer seating 66. The outer sleeve 124 further comprises slots 132a, 132b configured to receive the tongues 129a, 129b. When the tongues 129a, 129b are received into the slots 132a, 132b, the inner sleeve 122 and the outer sleeve 124 are rotationally locked in relation to each other. When the first protrusion 126 and the second protrusion 128 are in alignment, the tongues 129a, 129b are positioned in the first slots 132a, and when the first protrusion 126 and second protrusion 128 are out of alignment the tongues 129a, 129b are received in the second slots 132b. Hence, when the atomizer lock 120 is in an open position and when the atomizer lock 120 is in a closed position, the tongues 129a, 129b are received inside the slots 132a, 132b. This enables the atomizer lock 120 to provide a bi-stable operation and a haptic feedback to the user such that it becomes clear when the atomizer 12 is locked and released from the atomizer seating 66. The placement of the tongues 129a, 129b in the first slots 132a and the second slots 132b therefore respectively defines the aligned and misaligned positions of the first protrusion 126 and the second protrusion 128 with respect to one another by rotationally locking the inner sleeve 122 and the outer sleeve 124 in place until a sufficient torque is applied to move the tongues 129a, 129b from one slot to the other. The resilient tongues 129a, 129b may further comprise a convex protrusion or a bulging portion 130. The convex protrusion 130 is configured to guide the resilient tongues 129a, 129b into and out from the slots 132a, 132b. The resilient tongues are only locked inside the slots 132a, 132b until a sufficiently large torque is applied to the inner sleeve 122.

[0108] The torque can be applied to the inner sleeve by manually rotating the atomizer 12. This is because the atomizer 12 is coupled to the inner sleeve 122 via the protrusion 128 in the inner sleeve 122.

[0109] Alternatively, in an embodiment illustrated in FIGS. 7a to 7d, the power supply portion 6 comprises an actuator 70 in the form of a rotating ring or sleeve 70 and is located on the exterior housing of the power supply portion 6. The rotating ring 70 is operationally connected to the inner sleeve 122 such that they rotate in unison. The actuator 70 can thus be used to lock in the atomizer 12 into the atomizer seating 66.

[0110] It is advantageous to provide a biased abutment surface 72 in the atomizer seating 66. The biased abutment surface 72 can be configured as an electrical terminal. The biased abutment surface 72 is thus biased against a corresponding electrical connection portion of the atomizer 12.

[0111] The biased abutment surface 72 is coupled to a biasing member 74 such as a compression spring. The biasing member 74 has an upper end in contact with the biased surface 72 and a lower end in contact with a stationary surface 75 inside the power supply portion 6. In the embodiment illustrated in FIGS. 7b and 7c, the stationary surface 75 remains in the same position within the power supply portion 6. The biased surface 72 is configured to move between an ejection position and retracted position. The biased surface 72 can be a surface of a cylinder. The cylinder has a closed end, configured as the biased surface and an open end through which the spring exits. The open end of the cylinder can be provided with a circumferential flange which extends outwardly in the radial direction of the biased abutment member.

[0112] When the atomizer 12 is arranged in the atomizer seating 66, such that annular ridge 21 of the atomizer rests against the support surface 123, the bottom of the atomizer displaces the biased abutment surface 72 downward into the power supply portion thereby compressing to the biasing member 74 from an equilibrium state (i.e. uncompressed or at rest state) to a compressed state between the biased surface 72 and the stationary surface 75. As previously described, the first protrusion 126 locks the atomizer 12 in place in the atomizer seating 66 when the first protrusion 126 and second protrusion 128 are out of alignment; this maintains the compression applied to the biasing member 74.

[0113] The biased abutment surface 72 acts as an ejection mechanism to the atomizer 12 when the atomizer lock 120 is in an open position, such that the atomizer 12 can be released from the atomizer seating 66 without having to manually touch the atomizer 12. This avoids the user from being in contact with liquid when replacing a used atomizer 12.

[0114] It is preferable to replace the atomizer 12 after certain durations of use. When the atomizer 12 has been used, it can sometimes be covered with vaporization liquid. It is therefore advantageous if the user can discard the atomizer 12 without touching it. The biased abutment surface 72 is also configured to apply a biasing force onto the bottom portion 13 of the atomizer 12.

[0115] The biased abutment surface 72 therefore urges the atomizer 12 out from the atomizer seating 66. An atomizer ejection mechanism is therefore provided by the combination of the atomizer lock 120 and the biased abutment surface 72. The actuator 70 (rotating sleeve) is rotated to release/unlock the atomizer 12 from the atomizer seating 66 and the biased abutment surface ejects the atomizer 12 from the atomizer seating 66. That is to say, when the first protrusion 126 and second protrusion 128 are brought into alignment, such that the first protrusion 126 is no longer locking the atomizer 12 in the atomizer seating 66, the biasing applied by the biasing member 74 forces the atomizer 12 from the atomizer seating 66 as the compression is released and the biasing member 74 moves from a compressed state to an equilibrium state.

[0116] To reduce the risk of leakage, it is also advantageous to be able to close the liquid flow from the liquid store 10 to the atomizer 12 when the mouthpiece portion 4 is connected to the power supply portion 6. For instance, when travelling on an airplane, the low pressure in the ambient air at a high altitude will expand the air inside the liquid reservoir in response to an increase in altitude. This leads to the liquid being expelled with a greater force from the liquid store 10 to the atomizer 12. At the same time, less resistance is provided by the surrounding air, wherefore the liquid inside the liquid store 10 can more easily leave the liquid store 10 as the flow resistance is reduced at high altitude.

[0117] Referring back to FIG. 2a, the liquid store 10 is fluidically connected to the vapour outlet 9 in the mouthpiece 8 via the atomizer 12 and vapour tube 30. Hence, liquid may leak into the vapour flow channel and may potentially also leak out from the mouthpiece 8. Even if liquid only leaks into the vapour tube 30, it can reach the user as unvaporized liquid as the user inhales from the mouthpiece 8. Additionally, the fluid transfer element in the atomizer 12 can get oversaturated and the electronic cigarette may form projections of unvaporized liquid next time when the electronic cigarette 2 is being used.

[0118] As illustrated in FIGS. 8a to 8c and 9a to 9c, another embodiment of a leakage prevention system can be provided. The mouthpiece portion 4 is configured in a similar way as the embodiment previously discussed with regard to the valve 40. However, the proximal end of the power supply portion 6 is different, as will be described subsequently.

[0119] The leakage prevention system can easily be provided with the components of the valve 40 of the mouthpiece portion 4 and the atomizer lock 120. The leakage prevention system is based on a realization that the valve 40 is opened when the valve engaging portion of the atomizer 12a is located inside the liquid store 10. When the valve engaging portion of the atomizer 12a is located in the liquid store 10, the valve closing member 44 is released from the sealing surface 43 so that the outlet 7 is opened. Hence, the valve 40 is closed when the vaporizer 12 is removed from engagement with the valve closing member 44 of the liquid store 10.

[0120] Rather than removing the mouthpiece portion 4, however, the atomizer 12 can be retracted into the power supply portion 6 so that it no longer extends into the liquid store 10. Hence, the valve 40 can be released from the atomizer 12 and closed without disconnecting the mouthpiece portion 4 from the power supply portion 6.

[0121] The proximal portion of the power supply portion 6 comprises an inner sleeve 222 and an outer sleeve 224. The outer sleeve 224 further comprises an actuator 70 in the form of a rotatable sleeve 70. The rotatable sleeve 70 is operationally coupled to the inner sleeve 222. For instance, the rotatable sleeve 70 is operationally coupled to the inner sleeve 222 through a follower pin 71 located on the inner side of the actuator 70 and a thread 73 located on the outer sleeve 224.

[0122] As seen in FIGS. 8a to 8c, 9a to 9c and 12a to 12c the electronic cigarette 2 may be further provided with a guiding arrangement 500, configured to axially displace the inner sleeve 222 between an extended position and a retracted position.

[0123] In the illustrated embodiment, the guiding arrangement 500 comprises the axially displaceable inner sleeve 222, a pin 71 with a first portion located inside an axial groove 93 and a second portion located inside a guiding thread 95 on the inner side of the actuator 70′. Hence, the guiding arrangement 500 is configured to translate a rotational displacement of the actuator 70 to a linear (i.e. axial) displacement of the inner sleeve 222.

[0124] The inner sleeve 222 is thus axially moveable inside the power supply portion 6 between an extended position and a retracted position.

[0125] When the actuator 70 is rotated, the pin forces the threaded sleeve in a first direction or a second direction such that the axial position of the atomizer 12 is changed. The atomizer 12 can thus be positioned such that it extends into the liquid store, or that it is moved so that it is not actuating the valve 40 which then remains closed.

[0126] However, in a non-illustrated embodiment, it is also possible that the actuator 70 is linearly displaceable in the axial-longitudinal direction of the power supply portion and configured to move the inner sleeve in the axial direction.

[0127] In the extended position (i.e. in an operating position), as shown in FIG. 8b, the atomizer 12 is partially extending into the liquid reservoir 10 such that a fluidic connection between the liquid store 10 and the atomizer 12 is established. In the retracted position, as illustrated in FIG. 8c, the atomizer 12 is retracted into the body of the power supply portion 6 such that the atomizer 12 is no longer abutting against the valve closing member 44. In the retracted position, the liquid outlet 7 in the bottom of the liquid store 10 is closed. Hence, as the atomizer is connected to the inner sleeve 222, the axial displacement mechanism also enables the atomizer 12 to move between an extended position and a retracted position.

[0128] In the illustrated embodiment shown in FIGS. 8a to 8c, the engagement element 81 on the atomizer 12 can be in the form of an annular groove 81, the annular groove 81 defining an upper edge 82 toward the end of the atomizer 12 comprising the valve engaging portion 12a and a lower ledge 83 toward the end of the atomizer comprising the seating portion 12b. The inner sleeve 122 is provided with a connector 128 in the form of a clasp 128. In a preferred embodiment, a plurality of clasps 128 are provided. A plurality of clasps 128 provides a good connection between the clasps and the atomizer 12 such that the atomizer 12 can be securely connected to the inner sleeve 122. The clasps 128 are configured as resilient elongate members with projections 128a extending radially inward to sleeve at the atomizer receiving end. The clasps elastically deform over the lower edge 83 of the atomizer 12 when the atomizer 12 is pushed into the inner sleeve 222 such that the projections 128a are positioned in the annular groove 81 of the atomizer 12, abutting the lower edge 83, thereby clasping the atomizer in the inner sleeve 222 so that the atomizer 12 is engaged in the inner sleeve 222. The outer sleeve 124 is provided with axial slots 232 configured to guide the clasps 128 in the axial direction of the power supply portion 6. The electronic cigarette 2 in the embodiments of FIGS. 8a to 8c and 9a to 9c may also be provided with an atomizer ejection mechanism 800 by the combination of the clasps 128 which lock or retain the atomizer to the inner sleeve 222, and a movable biased abutment surface 72. In this way, the atomizer ejection mechanism 800 is configured to selectively retain/lock the atomizer 12 and eject the atomizer 12.

[0129] The biased abutment surface 72 is biased by a biasing member 74, a retaining flange 225 and a stationary biasing surface S. The biasing member 74, which can be a compression spring, is arranged in-between the biased surface 72 and the stationary biasing surface S. As the distance between the biasing surface 72 and the stationary biasing surface S varies, the level of compression of the biasing member 74 varies.

[0130] As seen in FIG. 8a, when the atomizer 12 is pushed into the inner sleeve 222, a bottom portion of the atomizer 12 can engage the biased abutment surface 72. The inner sleeve 222 can engage the biased abutment surface 72 via the flange 225 such that it can be retracted with the inner sleeve 222 into the body of the power supply. The flange 225 enables the biased abutment surface 72 to move in unison with the inner sleeve 222 as it is retracted into the power supply portion 6.

[0131] As is presented in FIG. 8a, before the atomizer 12 is engaged in the inner sleeve 222, the biasing member 74 is uncompressed. The biased abutment surface 72 is not pushed against the biasing surface S and the biasing member 74 is free from compression. However, when the atomizer 12 is pushed into and engaged in the inner sleeve 222 in an operating mode, as presented in FIG. 8b, the biased abutment surface 72 is pushed toward the biasing surface S and a compression is applied to the biasing member 74 between the biased abutment surface 72 and the biasing surface S.

[0132] As is presented in FIG. 8c, the inner sleeve 222 can be retracted into the outer sleeve 224. The inner sleeve 222 clasps the atomizer 12 and so when the inner sleeve 222 is retracted it retracts the atomizer 12 into the outer sleeve, away from the mouthpiece portion. Consequently, the valve engaging portion 12a of the atomizer 12 no longer engages the valve closing member 44 of the mouthpiece portion 4, and the biasing member 42 of the mouthpiece portion 4 biases the closing member 44 to the closed position, thereby closing the liquid opening of the liquid store 10 of the mouthpiece portion 4. As the atomizer 12 is retracted, the bulges 127 of the outer sleeve 224 engage the upper ledge 82 of the annular groove of the atomizer 12 thereby providing a stopping position such that the atomizer cannot be retracted further. The abutment of the upper ledge 82 against the bulges 127, when coupled with the further retraction of the inner sleeve 222, causes the clasps 128 to elastically deform over the lower ledge 83 when a great enough force is applied thereby releasing the atomizer 12 from the inner sleeve 222. When the projections 128a of the clasps 128 move over the lower ledge 83 the movement creates a haptic feedback to the user which indicates that the valve in the electronic cigarette is closed as the valve engaging portion 12a of the atomizer 12 has been retracted from the closing member of the mouthpiece. As the inner sleeve 222 moves further into the outer sleeve 224, the biasing surface S is no longer in contact with the biasing member 74, whereby the biased abutment surface 72 no longer applies an expelling force to the atomizer 12. The atomizer 12 is disengaged from the inner sleeve 222 before the biasing surface S has retracted enough to suitably remove the compressive force from the biasing member 74. This can be achieved either by the inner sleeve 222 retracting before the biasing surface S arranged on element 77 retracts, or by the biasing surface S arranged on element 77 retracting simultaneously but more slowly than the inner sleeve 222.

[0133] If the mouthpiece portion is removed, and the inner sleeve 222 is retracted and the consequent abutment of the upper ledge 82 against the bulges 127 causes the clasps 128 to elastically deform over the lower ledge 83, thereby disengaging the atomizer 12 from the inner sleeve 222, and atomizer ejection is achieved. As noted, the atomizer 12 disengages from the inner sleeve 222 before or at the same time the biasing surface disengages from the biasing member such that the biasing member is still under a compressive force when the atomizer is disengaged. As a consequence of the atomizer disengaging from the inner sleeve the biasing force applied by the biasing member 74 to the biased abutment surface 72 by the compression is released so as to eject the atomizer 12 from the power supply portion. Advantageously, the flange or stationary surface 225 engages the biased abutment surface during the ejection to prevent the biased abutment surface itself from also being ejected.

[0134] As illustrated in FIG. 8c, the biased abutment surface 72 can be released from engagement with the bottom portion of the atomizer 12 when the inner sleeve 222 is in a retracted position. The biased surface can be shaped as a cylinder having a closed end configured as the biased surface and an open end through which the spring exits. The biased abutment surface 72 has its lower end abutting against a stationary surface 225. The stationary surface remains in the same position within the power supply portion 6. The open end of the cylinder can be provided with a flange. The cylinder is configured to move in the axial direction in unison with the inner sleeve 122. The inner sleeve may therefore be provided with an abutment 225 located vertically above the cylinder flange portion. When the atomizer 12 is placed in a fully retracted position, the biased abutment surface 72 is retracted and is no longer in contact with the bottom portion of the atomizer. The biased abutment surface 72 can be configured as an electrical terminal. The terminal is thus biased against a corresponding electrical connection portion of the atomizer 12 when the inner sleeve 222 is extended outwardly from the outer sleeve 224. Advantageously, when the inner sleeve is retracted, and the biased abutment surface 72 is no longer is in contact with the bottom portion of the atomizer, the atomizer is electrically disconnected from the electrical terminal thereby ensuring the atomizer is not inadvertently switched on when not in use.

[0135] To re-engage the atomizer 12 with the inner sleeve 222, the inner sleeve 222 can be extended upwards against the atomizer 12 such that the clasps 128 are extended outwardly from the outer sleeve 224 such that the clasps re-engage with the atomizer 12 in the annular groove 81. The valve engaging portion 12a of the atomizer 12 abuts the mouthpiece portion 4 and an opposing force is applied to the atomizer 12; this leads to the projections 128a of the clasps 128 moving over the lower ledge 83 into the annular groove 81 of the atomizer such that the atomizer 12 is again held by the clasps 128. When the projections 128a of the clasps 128 move back over the lower ledge 83 the movement creates a haptic feedback to the user which indicates that the valve in the electronic cigarette is again opened as the valve engaging portion 12a of the atomizer 12 is again extended so as to urge the closing member of the mouthpiece to the open position.

[0136] The inner sleeve 222 can be moved further in the axial direction in relation to the outer sleeve 224 such that the biasing force from the biased surface 72 exceeds the radial biasing force of the clasps 128. Hence, when the biasing force from the ejector surface exceeds the radial biasing force of the clasps 128, the atomizer 12 is ejected from the atomizer seating 66. The inner sleeve 122 is thus configured to grasp the atomizer 12, when the clasps 128 engage the lower ledge 83 of the atomizer 12, and move the atomizer 12 in the axial direction further into the power supply portion 6.

[0137] It is also advantageous to provide a leakage reduction system for refilling the liquid store 10 which is configured to interact with the valve 40 of the mouthpiece portion 4. FIGS. 10a to 10d illustrate a refill bottle 90 configured to be used together with the previously described mouthpiece portion 4 of the present invention. The refill bottle 90 comprises a liquid reservoir 92 a liquid transfer arrangement 96. The refill bottle 90 may also comprise a cap 94 to protect the liquid transfer arrangement 96. The liquid reservoir 92 is preferably made from a flexible material such that it can be squeezed to expel liquid. The present refill bottle 90 enables to balance the volume of liquid and air inside the liquid store. As illustrated in FIGS. 10a to 10d, the liquid transfer arrangement 96 comprises a housing 98, a reservoir connection portion 99 and a refilling valve 100. The refilling valve 100 has a plunger 106 axially moveable within the housing 98. The liquid transfer arrangement 96 can be fixedly connected to a refill bottle 90 through e.g. an ultrasonic heat treatment. Alternatively, the liquid transfer arrangement 96 can be releasably connected to the liquid reservoir 92 through a threaded connection 160 (as seen in the figures).

[0138] The plunger 106 has a first end configured as a liquid delivery portion 108 and a second end configured as a liquid intake portion 112. The liquid delivery portion 108 is located outside housing and is configured to be insertable into the mouthpiece portion (the refill side) 4 of the electronic cigarette 2. The liquid intake portion 112 is located inside the housing on the opposite end of the plunger 106.

[0139] The liquid intake portion 112 comprises at least one liquid inlet 114. The liquid inlet in the liquid intake portion is in fluidic communication with the liquid reservoir 92. The liquid delivery portion 108 comprises at least one liquid outlet 110. The liquid outlet 110 is configured to deliver liquid into the liquid store 10 of the mouthpiece portion 4 in the electronic cigarette 2. The liquid inlet 114 and the liquid outlet 110 are in fluid communication by a channel 107 connecting them within the plunger 106. The liquid can advantageously be expelled by squeezing the refill bottle 90 and holding it upside down.

[0140] The plunger 106 is configured to move in the axial direction of the bottle 90 between and extended position and a depressed position. In the extended position the plunger 106 is extending out from the housing 98 at its maximum such that the liquid inlets 112, 114 are closed and in the retracted position, the plunger 106 is retracted against a biasing member 104 into the housing 98 such that the liquid inlets 114 are in fluid communication with the liquid in the reservoir 92. The plunger 106 is connected to the biasing member 104 which is configured to bias the plunger 106 into the extended position. The extended position is thus a rest position of the plunger 106. The biasing member 104 can be a compression spring or any elastic resilient material. The plunger 106 can be depressed by applying an axial force exceeding the biasing force, whereby the refill bottle 90 is open.

[0141] It is desirable to fixedly connect the refill bottle 90 to the mouthpiece portion 4 during refilling to ensure that the valves of the refill bottle and the mouthpiece portion are in a correct axial position. The housing 98 of the refill bottle 90 and the mouthpiece portion 4 may therefore further comprise an inter-engaging locking mechanism. The locking mechanism is configured to releasably connect the mouthpiece portion and the refill bottle during refilling. The inter-engaging locking arrangement may be configured as a bayonet coupling. The housing of the fluid transfer arrangement may therefore be provided with a locking element 115, such as a locking pin. In the illustrated embodiment, the locking pin 115 may extend in the transverse direction (in relation to the axial direction of the bottle). The mouthpiece portion of the electronic cigarette will therefore be provided with marching cut-out and groove. Alternatively, in a non-illustrated embodiment, the inter-engaging locking arrangement may be provided as a screw connection.

[0142] As best seen in FIGS. 11a to 11d, a fluidic connection between the mouthpiece portion 4 and the refill bottle 90 is established when the mouthpiece portion 4 and the liquid transfer arrangement 96 are connected.

[0143] In their rest position (when they are not connected), the liquid store 10 and the refilling valve 100 are both biased into a closed position. However, the valve 40 of the liquid store and the valve 100 of the refill bottle are opened when the refill bottle 90 and the mouthpiece portion 4 are engaged with each other. The plunger 106 of the refill bottle 90 can be depressed by engagement with the closing member 44 of the valve 40 in the mouthpiece portion 4. In the same way, the closing member 44 in the mouthpiece portion 4 is moved upwards away from the sealing surface such that the liquid opening 7 in the bottom surface S2 of the liquid store 10.

[0144] In order to avoid leakage and expulsion of excess liquid that does not enter the liquid store in the mouthpiece portion, it is desirable that the liquid store 10 of the mouthpiece portion 4 remains open longer than the refill bottle 90 in order to receive liquid whenever the valve in the refill bottle 90 is opened.

[0145] To this effect, the spring coefficient of the liquid store 10 in the mouthpiece portion 4 can be smaller than the spring coefficient of the refill recipient 90 such that the liquid store 10 opens before the refill bottle 90 and closes after the refill bottle 90. In an exemplary embodiment, the spring coefficient of the liquid refill bottle is 3 N/mm and the spring coefficient of the mouthpiece liquid store is 1.145 N/mm.

[0146] The liquid inlets 114 are preferably in a transverse direction in relation to the axial direction of the plunger 106. The housing 98 further comprises an annular seal arranged around the inner circumference of the housing. The seal is provided in an axial position which coincides with the position of the liquid inlets when the plunger 106 is in a rest position. Hence, the liquid inlets are closed off by the seal when the plunger is in an extended position.

[0147] The liquid outlets 110 in the plunger 106 can also be in the transverse direction in relation to the axial direction of the plunger 106. The top portion is thus configured to abut against the bottom flange of the closing member 44. A liquid passage is formed in the horizontal direction of the liquid store 10 as the sleeve is moved up. By having the liquid outlets arranged in the transverse direction, liquid can freely flow into the liquid store.

[0148] The liquid delivery portion of the plunger 106 further comprises an annular seal 113 which is located axially between the the liquid outlets 110 and the liquid inlets 114, wherein the seal 113 is configured to seal against an internal housing of the mouthpiece portion.

[0149] It will be understood that well known processes and elements have not been described in detail and may have been omitted for brevity. Specific steps, structures and materials have been described, by way of example. However, the present disclosure is not limited to those specific examples. It will be appreciated that some of the specific features described may be substituted for well-known alternatives, and that the method steps described may not necessarily be performed in the sequences given by way of example.

[0150] This disclosure has described a number of separate embodiments. However, it will be understood that features of different embodiments may be combined in any conceivable permutation. Other changes, substitutions, and alterations are also possible without departing from the scope of the claims.