阅读说明：本技术 用于蒸气产生装置的感应加热组件 (Induction heating assembly for a steam generating device ) 是由 丹尼尔·梵科 于 2018-12-20 设计创作，主要内容包括：一种用于蒸气产生装置(10)的感应加热组件(20),该感应加热组件包括感应线圈(30)以及被定位成与感应线圈(30)相邻的低通滤波器(34)。低通滤波器(34)电连接至感应线圈(30)以用作感应线圈(30)的低通滤波器,并且被成形为基本上跨过感应线圈(30)的至少一侧延伸以提供用于感应线圈(30)的电磁屏蔽件。(An induction heating assembly (20) for a vapor-generating device (10) includes an induction coil (30) and a low pass filter (34) positioned adjacent to the induction coil (30). The low pass filter (34) is electrically connected to the induction coil (30) to act as a low pass filter for the induction coil (30) and is shaped to extend substantially across at least one side of the induction coil (30) to provide an electromagnetic shield for the induction coil (30).)

1. An induction heating assembly (20) for a steam generating device (10), the induction heating assembly (20) comprising:

an induction coil (30); and

a low pass filter (34) positioned adjacent to the induction coil (30) and shaped to extend substantially across at least one side of the induction coil (30) to provide an electromagnetic shield for the induction coil (30).

2. The induction heating assembly (20) of claim 1, further comprising:

a power supply (16) arranged to provide power to the induction coil (30); and

a heating compartment (22) in communication with the air outlet (14).

3. The induction heating assembly (20) according to claim 2, wherein the low pass filter (34) is positioned between the induction coil (30) and the power source (16).

4. The induction heating assembly (20) according to claim 2, wherein the low pass filter (34) is positioned between the induction coil (30) and the air outlet (14).

5. The induction heating assembly (20) of claim 2, further comprising: an air inlet (18) in communication with the heating compartment (22), wherein the low pass filter (34) is positioned between the air inlet (18) and the power source (16).

6. The induction heating assembly (20) according to claim 1 or claim 2, further comprising: a resonant capacitor (42), wherein the low pass filter (34) is positioned between the induction coil (30) and the resonant capacitor (42).

7. The induction heating assembly (20) according to any one of the preceding claims, wherein the low pass filter (34) comprises a coil (36).

8. The induction heating assembly (20) of claim 7, wherein the low pass filter coil (36) comprises a flat coil extending in a plane defined by a winding direction of the coil.

9. The induction heating assembly (20) of claim 8,

the induction coil (30) is helical;

the low pass filter coil (36) is positioned at an axial end (38, 40) of the helical induction coil (30); and is

The plane of the low pass filter coil (36) is substantially perpendicular to the axial direction of the helical induction coil (30).

10. The induction heating assembly (20) of any one of claims 1, 7 and 8,

the induction coil (30) is helical; and is

The low pass filter (34) is arranged to substantially cover the elongated side of the helical induction coil (30).

11. The induction heating assembly (20) according to any one of claims 7 to 10, wherein the low pass filter (34) comprises a plate-like member (44) comprising a ferromagnetic material and the low pass filter coil (36) is positioned on the plate-like member (44).

12. The induction heating assembly (20) according to claim 11, wherein the low pass filter comprises two plate-like members (44a, 44b) comprising ferromagnetic material, and the low pass filter coil (36) is positioned between the plate-like members (44a, 44 b).

13. An induction heating assembly (20) as claimed in claim 11 or claim 12, wherein the or each plate-like member (44, 44a, 44b) comprises a ferromagnetic material having low electrical conductivity and high magnetic permeability.

14. A vapor-generating device (10) comprising:

the induction heating assembly (20) of any preceding claim;

a power supply (16) arranged to provide power to the induction coil (30);

a heating compartment (22) arranged to receive an inductively heatable cartridge (24);

an air inlet (18) arranged to provide air to the heating compartment (22); and

an air outlet (14) in communication with the heating compartment (22).

Technical Field

The present disclosure relates to an induction heating assembly for a steam generating device. Embodiments of the present disclosure also relate to a vapor generation device.

Background

Devices that heat, rather than burn, a vaporizable material to produce vapor for inhalation have gained popularity in recent years.

Such devices may use one of a number of different approaches to provide heat to a substance. One such approach is a vapor generation device that employs an induction heating system. In such a device, the device is provided with an induction coil (hereinafter also referred to as inductor) and the vaporizable substance is provided with a susceptor. When the user activates the device, power is supplied to the inductor, which in turn generates an alternating electromagnetic field. The susceptor couples with an electromagnetic field and generates heat that is transferred to the vaporizable material, such as by conduction, and when the vaporizable material is heated, a vapor is generated.

Such an approach potentially provides better control over heating and therefore vapor generation. However, a disadvantage of using an induction heating system is that the electromagnetic field generated by the induction coil may leak, and thus it is necessary to solve this disadvantage.

Disclosure of Invention

According to a first aspect of the present disclosure there is provided an induction heating assembly for a vapour generating device, the induction heating assembly comprising:

an induction coil; and

a low pass filter positioned adjacent to the induction coil and shaped to extend substantially across at least one side of the induction coil.

The low pass filter is electrically connected to the induction coil to function as a low pass filter of the induction coil. The low pass filter is also configured to provide an electromagnetic shield for the induction coil. In this way, a single electronic component may be provided to serve as both a low pass filter and an electromagnetic shield for the electronic control circuitry of the induction heating assembly. Thus, the construction of the induction heating assembly is simplified since fewer electronic components need to be used. The use of fewer electronic components results in a reduction in both the size and manufacturing cost of the induction heating assembly.

According to a second aspect of the present disclosure, there is provided a vapor generation device comprising:

an induction heating assembly according to the first aspect of the present disclosure;

a power supply arranged to provide power to the induction coil;

a heating compartment arranged to receive an inductively heatable cartridge;

an air inlet arranged to provide air to the heating compartment; and

an air outlet in communication with the heating compartment.

The induction heating assembly may comprise a power source, for example a battery, arranged to provide power to the induction coil. The induction heating assembly may comprise a heating compartment in communication with the air outlet. The heating compartment may be arranged to receive an inductively heatable cartridge.

The low pass filter may be positioned between the induction coil and the power supply.

The low pass filter may be positioned between the induction coil and the air outlet.

The induction heating assembly may include an air inlet in communication with the heating compartment, and the low pass filter may be positioned between the air inlet and the power source. This arrangement allows the induction heating assembly, and hence the vapour generating device, to be made compact.

The induction heating assembly may include one or more resonant capacitors, and the low pass filter may be positioned between the induction coil and the one or more resonant capacitors. Thus, the one or more resonant capacitors are protected from electromagnetic exposure.

The low pass filter may comprise a coil. The low pass filter coil may comprise a flat coil, which may extend in a plane defined by the coil winding direction.

The induction coil may be helical.

The low pass filter coil may be positioned at an axial end of the helical induction coil. The plane of the low pass filter coil may be substantially perpendicular to the axial direction of the helical induction coil.

The low pass filter may be arranged to substantially cover the elongated side of the helical induction coil.

The low-pass filter may comprise a plate-like member comprising ferromagnetic material, and the low-pass filter coil may be positioned on the plate-like member. This arrangement increases the inductance of the low pass filter and the EM shield performance.

The low-pass filter may comprise two plate-like members comprising ferromagnetic material, and the low-pass filter coil may be positioned between the plate-like members. This arrangement also increases the inductance of the low pass filter and the EM shielding performance.

The or each ferromagnetic plate-like member may be circular and may for example comprise a ferromagnetic disc, but other shapes may also be used.

The or each ferromagnetic plate-like member may comprise a ferromagnetic material having low electrical conductivity and high magnetic permeability, for example a ferrite ceramic.

The induction heating assembly may be arranged to operate, in use, by a fluctuating electromagnetic field having a magnetic flux density of between about 20mT to about 2.0T of the highest concentration point.

The induction heating assembly may include a power supply and circuitry, which may be configured to operate at high frequencies. The power supply and circuitry may be configured to operate at a frequency of between about 80kHz and 500kHz, possibly between about 150kHz and 250kHz, and possibly about 200 kHz. Depending on the type of inductively heatable susceptor used, the power supply and circuitry may be configured to operate at higher frequencies, such as frequencies in the MHz range.

The low pass filter may have a cut-off frequency of approximately between 100kHz and 600 kHz. In some embodiments, the low pass filter may have a cutoff frequency of about 250 kHz. In other embodiments, the cut-off frequency of the low-pass filter may be between about 280kHz and 300 kHz.

The induction coil may typically comprise litz (L itz) wire or litz cable, although the induction coil may comprise any suitable material.

Although the induction heating assembly may take any shape and form, it may be arranged to substantially take the form of an induction coil to reduce excess material usage. As mentioned above, the shape of the induction coil may be substantially helical.

The circular cross-section spiral induction coil facilitates insertion of the inductively heatable cartridge into the induction heating assembly and ensures uniform heating of the inductively heatable cartridge. The resulting shape of the induction heating assembly is also comfortable for the user to hold.

The inductively heatable cartridge may include one or more inductively heatable susceptors. The or each susceptor may comprise, but is not limited to, one or more of aluminium, iron, nickel, stainless steel and alloys thereof (e.g. nickel chromium or nickel copper alloys). By applying an electromagnetic field in its vicinity, the or each susceptor may generate heat due to eddy currents and hysteresis losses, thereby causing conversion of electromagnetic energy to thermal energy.

The inductively heatable cartridge may include a vapor-generating substance inside the gas permeable shell. The gas permeable housing may comprise a gas permeable material that is electrically insulating and non-magnetic. The material may have high air permeability to allow air to flow through the material having high temperature resistance. Examples of suitable breathable materials include cellulose fibers, paper, cotton, and silk. The breathable material may also be used as a filter. Alternatively, the inductively heatable cartridge may comprise a vapour generating substance wrapped in paper. Alternatively, the inductively heatable cartridge may comprise a vapour-generating substance held inside a material that is air impermeable but comprises suitable perforations or openings to allow air flow. Alternatively, the inductively heatable cartridge may be comprised of the vapor-producing substance itself. The inductively heatable cartridge may be formed substantially in the shape of a rod.

The vapour-generating substance may be any type of solid or semi-solid material. Exemplary types of vapor producing solids include powders, particulates, pellets, chips, threads, granules, gels, strips, loose leaves, chopped filler, porous materials, foams, or sheets. The substance may comprise plant-derived material, and in particular, the substance may comprise tobacco.

The vapour-generating substance may comprise an aerosol former. Examples of aerosol formers include polyols and mixtures thereof, such as glycerol or propylene glycol. Typically, the vapour-generating substance may comprise an aerosol former content of between about 5% and about 50% (dry basis). In some embodiments, the vapor-generating material may include an aerosol former content of about 15% (dry weight basis).

Also, the vapour-generating substance may be the aerosol former itself. In this case, the vapor-generating substance may be a liquid. Also in this case, the inductively heatable cartridge may comprise a liquid retaining substance (e.g. a fibre bundle, a porous material such as ceramic, etc.) which retains the liquid to be vaporised and allows vapour to be formed and released/discharged from the liquid retaining substance, for example towards an air outlet, for inhalation by a user.

Upon heating, the vapor-generating substance may release volatile compounds. The volatile compounds may include nicotine or flavor compounds such as tobacco flavors.

Since the induction coil generates an electromagnetic field when it is operated to heat the susceptor, in operation any component comprising the inductively heatable susceptor will be heated when placed in the vicinity of the induction coil and this does not impose restrictions on the shape and form of the body received by the heating compartment. In some embodiments, the inductively heatable cartridge may be cylindrical in shape and the heating compartment is therefore arranged to receive a substantially cylindrical vaporisable article.

The ability of the heating compartment to receive a substantially cylindrical inductively heatable cartridge to be heated is advantageous because normally vaporizable substances, in particular tobacco products, are packaged and sold in cylindrical form.

Drawings

FIG. 1 is a diagrammatic illustration of a vapor-generating device including an induction heating assembly according to a first embodiment of the present disclosure;

FIG. 2 is a diagrammatic illustration of a vapor-generating device including an induction heating assembly according to a second embodiment of the present disclosure;

FIGS. 3a and 3b are graphical illustrations of a first example of a low pass filter of the induction heating assembly of FIGS. 1 and 2; and is

Fig. 4a and 4b are graphical illustrations of a second example of a low pass filter of the induction heating assembly of fig. 1 and 2.

Detailed Description

Embodiments of the present disclosure will now be described, by way of example only, and with reference to the accompanying drawings.

Referring initially to FIG. 1, a vapor-generating device 10 according to an example of the present disclosure is diagrammatically illustrated. The vapor-generating device 10 includes a housing 12, a portion of which is shown in FIG. 1. When the device 10 is used to generate vapor for inhalation, a mouthpiece (not shown) may be mounted on the device 10 at the air outlet 14. The mouthpiece has the ability for the user to easily inhale the vapor generated by the device 10. The apparatus 10 includes a power supply 16 and control circuitry 17, which may be configured to operate at high frequencies. The power supply 16 typically includes one or more batteries capable of being inductively recharged, for example. The device 10 also includes a plurality of air inlets 18.

The vapor-generating device 10 includes an induction heating assembly 20 for heating a vapor-generating (i.e., vaporizable) substance. The induction heating assembly 20 includes a generally cylindrical heating compartment 22 arranged to receive a correspondingly shaped generally cylindrical inductively heatable cartridge 24 comprising a vaporizable substance 26 and one or more inductively heatable susceptors 28. The inductively heatable cartridge 24 typically includes an outer layer or membrane to contain the vaporizable material 26, where the outer layer or membrane is breathable. For example, the inductively heatable cartridge 24 may be a disposable cartridge 24 that contains tobacco and at least one inductively heatable susceptor 28.

The induction heating assembly 20 includes a helical induction coil 30 having a first axial end 38 and a second axial end 40 that extends around the cylindrical heating compartment 22 and that may be energized by the power supply 16 and the control circuitry 17. The control circuitry 17 comprises, among other electronic components, an inverter arranged to convert a direct current from the power source 16 into an alternating high frequency current for the induction coil 30. It will be appreciated by those skilled in the art that when the induction coil 30 is energized with an alternating high frequency current, an alternating and time varying electromagnetic field is generated. The alternating and time-varying electromagnetic field couples with the one or more inductively heatable susceptors 28 and generates eddy currents and/or hysteresis losses in the one or more inductively heatable susceptors 28, thereby causing them to generate heat. Heat is then transferred from the one or more inductively heatable susceptors 28 to the vaporizable substance 26, for example, by conduction, radiation, and convection.

The inductively heatable susceptor(s) 28 may be in direct or indirect contact with the vaporizable substance 26 such that when the susceptor 28 is inductively heated by the induction coil 30 of the induction heating assembly 20, heat is transferred from the susceptor(s) 28 to the vaporizable substance 26 to heat the vaporizable substance 26 and produce a vapor. The addition of air from the ambient environment through air inlet 18 facilitates vaporization of vaporizable substance 26. The vapour generated by heating the vaporisable substance 26 then leaves the heating compartment 22 through the air outlet 14 and may be inhaled, for example, by a user of the device 10 through a mouthpiece. The negative pressure created by the user drawing air from the air outlet 14 side of the device 10 using the mouthpiece can assist the air flow through the heating compartment 22, i.e., from the air inlet 18, through the heating compartment 22 along the inhalation passage 32 of the induction heating assembly 20, and out of the air outlet 14.

The induction heating assembly 20 includes a low pass filter 34 electrically connected to the induction coil 30. The low pass filter 34 functions as a low pass filter of the induction coil 30, and is configured to provide electromagnetic shielding to the induction coil 30, thereby reducing leakage of an electromagnetic field generated by the induction coil 30. The low pass filter 34 typically comprises a flat coil 36, such as illustrated in fig. 3a, which extends in a plane defined by the coil winding direction.

In the embodiment illustrated in fig. 1, the low pass filter 34 is positioned at a first axial end 38 of the induction coil 30, and the plane of the low pass filter coil 36 is substantially perpendicular to the axial direction of the induction coil 30. In this position, it will be seen that the low pass filter coil 36 extends substantially across one side of the induction coil 30 at a first axial end 38 of the induction coil 30, and the low pass filter coil 36 is positioned between the induction coil 30 and the power supply 16, and also between the air inlet 18 and the power supply 16.

In the illustrated embodiment, the induction heating assembly 20 includes one or more resonant capacitors 42, and the low pass filter coil 36 is advantageously positioned between the induction coil 30 and the one or more resonant capacitors 42 to protect the resonant capacitor(s) 42 from exposure to the electromagnetic field generated by the induction coil 30.

In another embodiment illustrated in fig. 2, the coil 36 forming the low pass filter 34 is positioned such that the coil substantially covers the elongated side of the induction coil 30, wherein the plane of the low pass filter coil 36 is arranged such that the plane is substantially parallel to the axial direction of the helical induction coil 30.

As described above, and with reference to fig. 3a and 3b, the low pass filter 34 typically includes a pancake coil 36. The low pass filter 34 further comprises a ferromagnetic plate-like member in the form of a ferromagnetic disc 44 having a circular cross-section corresponding for example to the coiled configuration of the low pass filter coil 36. As shown in fig. 3b, the low pass filter coil 36 is mounted on a disc 44, and the disc 44 is used as a magnetic core that increases the inductance of the low pass filter 34. Those skilled in the art will appreciate that a portion of the coil 36 extending radially outward from a central region of the coil 36 is not in contact with the circumferential extension below the coil 36.

Fig. 4a and 4b illustrate another embodiment of a low-pass filter 34 similar to the low-pass filter 34 illustrated in fig. 3a and 3b, wherein the low-pass filter coil 36 is positioned between two ferromagnetic plate-like members in the form of ferromagnetic discs 44a, 44 b. The use of two ferromagnetic disks 44a, 44b (instead of one ferromagnetic disk 44 as shown in fig. 3a and 3 b) provides a low pass filter 34 with a further increase in inductance.

The ferromagnetic disks 44, 44a, 44b comprise a ferromagnetic material having a low electrical conductivity and a high magnetic permeability. Ferromagnetic ceramics are one example of a suitable material. Also, those skilled in the art will appreciate that a portion of the coil 36 extending radially outward from a central region of the coil 36 does not contact the circumferential extension below the coil 36.

While exemplary embodiments have been described in the preceding paragraphs, it should be appreciated that various modifications may be made to these embodiments without departing from the scope of the appended claims. Thus, the breadth and scope of the claims should not be limited by any of the above-described exemplary embodiments.

Unless the context clearly requires otherwise, throughout the description and the claims, the words "comprise", "comprising", and the like are to be construed in an inclusive, rather than an exclusive or exhaustive sense, that is to say in the sense of "including but not limited to".