KR200495141Y1 - Non-combustion heated smoking device and heating assembly thereof - Google Patents

Abstract

The present invention relates to a non-combustion heated smoking device (10) and a heating assembly (100) thereof. The heating assembly 100 includes a pipe body 110 , a heating rod 140 and a heating piece 130 . A filter (120) is located within the pipe body (110), and the heating piece (130) has a first end (131) and a second end (132) opposite to each other.

Description

Non-combustion heated smoking device and heating assembly thereof

FIELD OF THE INVENTION The present invention relates to air heating technology, and more particularly to non-combustion heated smoking devices and heating assemblies thereof.

Currently, the toxicity of tobacco is one of the most serious public health problems worldwide. Numerous scientific evidence shows that smoking and secondary smoking exposure (secondhand smoke) seriously harm human health. According to statistics from the World Health Organization (WHO), the number of deaths caused by smoking worldwide can be as high as 6 million each year, ie an average of 1 person dies from smoking-related diseases every 6 seconds, and smokers Half of these can die prematurely from smoking, and the annual number of deaths among nonsmokers caused by secondary smoking exposure is approximately 600,000.

Due to the significant human dependence on tobacco products and the dual pressures of health faced by cancer and disease, the demand in the tobacco market is not only to give smokers the same excitement and pleasure as traditional cigarettes, but also to protect their health from harm. To provide products that can be protected. The non-combustion heated tobacco product directly heats the cigarette through the smoking device without generating smoke, so it can achieve the satisfaction close to that of a conventional cigarette, as well as reduce the generation and inhalation of harmful substances during combustion. And, as a result, it is the most innovative product that can have a confounding effect on cigarettes.

Generally, smoking devices using non-combustion heated technology include a heating assembly. Such conventional heating assemblies utilize direct conductive heating, which continuously heats the tobacco product in direct contact with the tobacco product to atomize the tobacco to produce smoke. However, this may result in non-uniform heating zones of the tobacco product, and portions of the tobacco product close to the heating assembly may be severely carbonized while portions of the tobacco product remote from the heating assembly may not be heated and atomized. .

Accordingly, there is a need to provide a non-combustion heating type smoking device capable of providing a uniform heating effect and a heating assembly thereof.

The heating assembly comprises: a pipe body defining an air inlet at its distal end, wherein a filter is located in the pipe body, the pipe body being divided by the filter into a first chamber and a second chamber; A heating rod accommodated in the second chamber, wherein a heating space is formed between the heating rod and an inner wall of the pipe body, the heating space having a spiral or stepped guiding passage therein a heating rod to form a; and a heating piece comprising first and second ends opposite one another, the second end having a size less than the size of the first end, the first end connecting to the filter and the second end is received in the first chamber, and the heating piece is guided out of the first chamber via a first conductive wire.

A non-combustion heated smoking device includes the heating assembly described above.

In the non-combustion heated smoking device and heating assembly thereof, the heating piece is guided out of the first chamber via the first conductive wire, the heating rod and the heating piece being controlled by circuits independent of each other; the heating rod and the heating piece are switched to the heating operation state at the same time after turning on the power, the heating piece is heated more rapidly to preferentially reach the atomization temperature of the tobacco product, and the heating piece is in contact with the tobacco product; As a result, said smoking devices are converted to usable state within a short period of time; The heating piece then stops working while the heating rod continues heating, so that the cold air entering the pipe body via the air inlet will be sufficiently heated after flowing through the spiral or stepped guiding passage. and the heated air flows through the filter into the first chamber and continuously and uniformly heats the tobacco product by radiation, resulting in better and faster heating effect.

In order to more clearly illustrate the technical solution according to the embodiment of the present invention or the technical solution in the prior art, the accompanying drawings for explaining the above embodiment or the prior art are briefly introduced below. The accompanying drawings in the following description are merely some embodiments of the present invention, and those of ordinary skill in the art can infer other obvious modifications from the accompanying drawings without any creative efforts.
1 is a schematic diagram of a heating assembly according to a first embodiment;
Fig. 2 is a cross-sectional view of the heating assembly shown in Fig. 1;
Fig. 3 is a measured plan view of the heating assembly shown in Fig. 1 viewed from another side;
4 is a cross-sectional view taken along line AA shown in FIG. 3 ;
Fig. 5 is another cross-sectional view of the heating assembly shown in Fig. 1;
Fig. 6 is a top view of the heating assembly shown in Fig. 1;
7 is a schematic diagram of a filter and heating piece according to an embodiment;
Fig. 8 is a plan view of the filter and heating piece shown in Fig. 7;
Fig. 9 is a measurement plan view of the filter and heating piece shown in Fig. 7;
10 is a cross-sectional view of a heating assembly according to a second embodiment;
11 is a cross-sectional view of a heating assembly according to a third embodiment;
12 is a cross-sectional view of a heating assembly according to a fourth embodiment;
13 is a cross-sectional view of a heating assembly according to a fifth embodiment;
14 is a cross-sectional view of an air inlet pipe connected to a pipe body according to an embodiment.

Hereinafter, embodiments of the present invention are disclosed in more detail with reference to the accompanying drawings. However, the various embodiments of the present invention may be embodied in many different forms and should not be construed as limited to the embodiments disclosed herein. Rather, these embodiments are listed so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

It should be understood that when one component is referred to as being “immobilized” to another component, it may be directly bound to the other component or intervening components may be present. When one component is referred to as being “bound” to another component, it may be directly bound or intervening components may also be present. Although the terms 'vertical', 'horizontal' and 'side to side' and similar expressions may be used herein to describe various components, these terms are used for purposes of illustration only, and to limit the invention to one embodiment only. It will be understood that it is not intended for

Unless stated otherwise herein, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that the terminology used herein is provided for the purpose of describing the embodiments in detail only and is not intended to limit the invention. Although the individual embodiments have been disclosed in turn, it is to be understood that the individual embodiments will not be standalone. A person skilled in the art, upon reading the present invention, clearly recognizes that the individual technical characteristics relevant to the individual embodiments may be arbitrarily combined between the individual embodiments as long as they do not conflict with each other. can do. Of course, the individual technical characteristics mentioned in the same embodiment may be arbitrarily combined as long as they do not conflict with each other.

1 , a non-combustible heated smoking device 10 according to one embodiment is capable of directly heating a tobacco product 20 without producing smoke by primarily non-burning heated techniques to achieve a cigarette-like satisfaction. However, the tobacco product 20 is not combusted to avoid generation and inhalation of harmful substances in the combustion process. The tobacco product 20 may be a plate leaf (tobacco sheet), a cigarette, shredded tobacco, and the like. In particular in the embodiment illustrated above the non-combustion heated smoking device 10 comprises a heating assembly 100 and a heating pipe (not shown). The tobacco product 20 is inserted into the component 100 along the direction indicated by the arrow in FIG. 1 .

Referring to Figure 1, the heating assembly 100 is mainly used to heat the sucked cold air to create a heated air stream, the heated air stream heats the tobacco product 20 by radiation, , where this heating is more uniform and a portion of the tobacco product 20 proximal to the heating assembly 100 is carbonized while a portion of the tobacco product 20 distal to the heating assembly 100 is insufficiently heated. can be effectively prevented.

2 to 6 , the heating assembly 100 according to the first embodiment includes a pipe body 110 , a filter 120 , a heating piece 130 , a heating rod 140 , and a heating wire 150 . do. In particular, in the illustrated embodiment, both ends of the heating wire 150 are electrically coupled to a power source or battery 30, respectively, while the heating rod 140 is connected to the power source or battery 30 via a conductive wire. not directly coupled In other words, while the heating rod 140 itself is not electrified to generate heat, heat is generated by the heating wire 150 and conducted to the heating rod 140 . Obviously, in alternative embodiments the heating rod 140 may be coupled directly to the power source or battery via a conductive wire.

One end of the pipe body 110 defines an air inlet 1231, and cold air is blown from the outside through the air inlet 1231 by a drawing force generated by a suction action into the pipe body 110 ) goes into The other end of the pipe body 110 defines an outlet 1111 , the cold air is heated to form a hot air stream, the hot air stream for heating the tobacco product 20 by radiation. It enters the heating pipe through an inlet 1111 . In particular, the airflow flows in the direction indicated by the arrow in FIG. 5 .

Referring to FIG. 14 , particularly in the embodiment illustrated above, the heating assembly 100 further comprises an air inlet tube 200 . The air inlet pipe 200 includes an inlet end 210 and an outlet end 220 . The side wall of the air inlet pipe 200 is sealed. The outlet end 220 communicates with the air inlet 1231 . When the suction action occurs, cold air enters the air inlet pipe 200 through the inlet end 210 and is discharged from the outlet end 220 , and then passes through the air inlet 1231 to the pipe body 110 . ) goes into Since the side wall of the air inlet pipe 200 is sealed, the cold air introduced through the inlet end 210 may only flow into the pipe body 110 through the outlet end 220 . No air leaks and no other air is entrained during the air guiding process, thereby ensuring a clean and pollution-free airflow source.

A one-way airflow sensor 230 is provided at the inlet end 210, which is configured to sense the airflow when a suction action occurs in order to record the effective number of suctions. For example, the unidirectional airflow sensor 230 may be a unidirectional microphone.

The pipe body 110 may be made of an insulating and thermally conductive material, so the pipe body 110 itself does not generate heat, but conducts the heat generated by the heating wire 150 . For example, the pipe body 110 may be made of a thermally conductive metal, a ceramic material, or other medium, and the pipe body 110 may also be made of an insulated thin aluminum material or the like.

7 to 9 , the filter 120 is located in the pipe body 110 . The filter 120 divides the pipe body 110 into a first chamber 110a and a second chamber 110b, and these chambers communicate with each other. The tobacco product 20 is received within the first chamber 110a, wherein the first chamber 110a has an inner diameter similar to the diameter of the tobacco product 20 for inserting and placing the tobacco product 20. have The heating rod 140 and the heating wire 150 are accommodated in the second chamber 110b. The height of the first chamber 110a is two-thirds the effective length of the tobacco product 20 .

The filtering holes 121 are disposed on the filter 120 , which can effectively prevent the residue of the tobacco product 20 from flowing out into the second chamber 110b. A heating space is formed between the heating rod 140 and the inner wall of the pipe body 110 , and the heating space forms a spiral or stepped guiding passage therein. A printed circuit 111 guided out by a circuit pin 112 may be provided on the sidewall of the second chamber 110b.

In particular, in the illustrated embodiment, the heating piece 130 and the filter 120 are integrally formed. Accordingly, the assembly process of the heating piece 130 and the filter 120 can be omitted, and the assembly is more convenient and effective. The filter 120 and the pipe body 110 are integrally formed, so the assembly process of the filter 120 and the pipe body 110 can be omitted, and the assembly becomes more convenient and effective. Obviously, in alternative embodiments the heating piece 130 and filter 120 may be separate structures. The filter 120 and the pipe body 110 may also be structures.

The heating piece 130 further includes a first end 131 and a second end 132 opposite to each other, the size of the second end 132 being greater than the size of the first end 131 . small. The first end 131 is connected to the filter 120 , and the second end 132 is accommodated in the first chamber 110a. In particular, the second end 132 may be a sharp end, which may be inserted into the tobacco product 20 .

When the tobacco product 20 is mounted into the first chamber 110a of the pipe body 110 , the second end 132 of the heating piece 130 is inserted into the tobacco product 20 . In particular, since the heating piece 130 is located in the middle part of the filter 120 , this is to prevent non-uniform heating caused by deflected insertion of the heating piece 130 to the tobacco product 20 . can be inserted into the midline of

In particular in the illustrated embodiment the first end 131 of the heating piece 130 extends through the filter 120 into the second chamber 110b. The first end 131 extending into the second chamber 110b is a certain distance from the heating rod 140 to prevent the heating piece 130 and the heating rod 140 from being electrically coupled to each other. are spaced apart from The first end 131 extending into the second chamber 110b can provide heat for heating the air in the second chamber 110b, thus further ensuring that the cold air is sufficiently heated. Obviously, in an alternative embodiment the first end 131 cannot extend through the filter 120 , but is integrally formed on the filter 120 .

The heating piece 130 is guided out of the first chamber 110a via a first conductive wire 133 . The heating piece 130 and the heating wire 150 are controlled by circuits independent of each other. In other words, the inversion of the heating piece 130 and the heating wire 150 is independent of each other and does not affect each other. For example, the sidewall of the pipe body 110 may define a wiring hole 134 for guiding the first conductive wire 133 out of the first chamber 110a, and then the wiring hole 134 ) is sealed with high-temperature tape to prevent air leaks.

A part of the side wall of the heating piece 130 accommodated in the first chamber 110a is printed with a heating circuit 135 for the purpose of rapid heating. Obviously, in an alternative embodiment, the heating circuit 135 of the heating piece 130 may be omitted, and the heating piece 130 is made of a material with better heating performance to achieve the purpose of rapid heating.

The heating piece 135 may be made of ceramic, zirconia, metal, or the like. The heating piece 130 has a thickness in the range of 0.35 mm to 0.6 mm to ensure strength of the heating piece 130 and also to facilitate insertion into the tobacco product 20 .

The heating piece 130 is connected to the first conductive wire 133 through a brazing process such as a high-temperature brazing process to withstand the temperature of the high-temperature airflow. Roughly, the temperature control method for the surface of the heating piece 130 is to measure the temperature of the surface of the heating piece 130 through the resistance change rate of the heating circuit 135 after heating .

In particular in the illustrated embodiment the heating rod 140 is accommodated in the pipe body 110 . The heating rod 140 may be made of an insulating, heat-resistant and thermally conductive material, so the heating rod 140 itself does not invert to generate heat, whereas heat is generated by the heating wire 150 Conducted to the heating rod (140). For example, the heating rod 140 may be made of ceramic, insulating metal, or the like. The heating rod 140 may have a cylindrical shape.

In particular, in the illustrated embodiment, a temperature sensor 160 is additionally provided on the outer sidewall of the pipe body 110, and the temperature sensor 160 quickly and accurately monitors the temperature of the heating rod 140 after heating. used to measure For example, the temperature sensor 160 may be a thermistor such as an NTC thermistor. After sensing the temperature of the heating rod 140, the temperature sensor 160 feeds back the temperature to a control system (eg, a microcontroller unit), and the control system The supply current is continuously adjusted according to the program instructions so that the temperature of the heating rod 140 is always within the controllable range.

In particular, in the illustrated embodiment, the outer sidewall of the heating rod 140 defines a spiral groove 141 , and the heating wire 150 is formed along the spiral groove 141 around the outer sidewall of the heating rod 140 . is spirally wound. The spiral guiding passage 11a is cooperatively formed by the heating wire 150 , the outer sidewall of the heating rod 140 , the spiral groove 141 , and the inner wall of the pipe body 110 . The height of the spiral groove 141 is greater than the diameter of the heating wire 150 in order to secure the size of the guiding passage 11a. Since the heating wire 150 is spirally wound around the outer sidewall of the heating rod 140 along the spiral groove 141 , the heating wire 150 not only directly heats the airflow, but also by the heating wire 150 . The generated heat may further increase the temperature of the heating rod 140 , and the heated heating rod 140 may heat the airflow.

In particular, in the illustrated embodiment, the heating rod 140 defines through-holes 142 extending along the axial direction of the heating rod 140 through both ends of the heating rod 140 . One end 151 of the heating wire 150 is extended into the pipe body 110 via one end of the pipe body 110, and the other end 152 of the heating wire 150 is a heating rod ( 140) After being wound around, it extends out of the pipe body 110 from the end of the pipe body 110 via the through hole 142. In other words, one end 151 of the heating wire 150 and the other end 152 of the heating wire 150 extend inside or outside the pipe body 110 from the same end of the pipe body 110, Accordingly, when the heating wire 150 passes through the through hole 142 , the heating wire 150 may heat the heating rod 140 from the inside.

A part of the heating wire 150 wound around the outer sidewall of the heating rod 140 heats the outside of the heating rod 140 , and extends through the through hole 142 located inside the heating rod 140 . A portion of the heating wire 150 heats the inside of the heating rod 140 , and thus the inside and outside of the heating rod 140 are uniformly heated at the same time, thereby increasing the heating rate of the heating rod 140 . . After being guided out of the pipe body 110 , the two sides of the heating wire 150 are electrically coupled to a power source or a battery 30 to generate heat when inverted.

One end of the heating rod 140 adjacent the filter 120 defines a side hole 143 on its sidewall, the side hole 143 communicating with the through hole 142 . After the heating wire 150 is wound around the outer sidewall of the heating rod 140 , the other end of the heating wire 150 is extended into the through hole 142 via the side hole 143 .

The filter 120 may be made of a thermally conductive material, and the material of the filter 120 may further have easy cleaning properties. For example, the filter 120 may be made of metal, stainless steel, or the like.

In particular, in the illustrated embodiment, one end of the second chamber 110b is in an open state, and an adjacent plate 144 is provided at one end of the heating rod 140 that is far from the filter 120, and the A through hole 142 extends through the adjacent plate 144 . The outer diameter of the adjacent plate 144 is greater than the inner diameter of the pipe body 110, and the adjacent plate 144 is adjacent to the end of the pipe body 110. The air inlet 1231 is It may be an opening disposed on the edge of the plate 144, or it may be a hole disposed between the edge of the adjacent plate 144 and the through hole 142. The direction indicated by the arrow in Fig. 5 is the direction of the airflow. .

Roughly, the assembly process of the heating assembly 100 shown in FIG. 5 is as follows:

After inserting one end of the heating wire 150 into the air inlet 1231 , the heating wire 150 is spirally wound into the spiral groove 141 on the outer sidewall of the heating rod 140 , and then to guide the other end of the heating wire 150 out through the through hole 142 . The assembled heating wire 150 and the heating rod 140 are inserted into the second chamber 110b until the adjacent plate 144 is adjacent to the end of the pipe body 110 . The guiding passage 11a is cooperatively formed by the heating wire 150 , the outer sidewall of the heating rod 140 , the spiral groove 141 , and the inner wall of the pipe body 110 .

Referring to FIG. 10 , in the heating assembly 100 according to the second embodiment, the heating wire 150 is spirally wound around the outer sidewall of the heating rod 140 , and the spiral guiding passage 11a is It is cooperatively formed by the heating wire 150 , the outer sidewall of the heating rod 140 , and the inner wall of the pipe body 110 . In the illustrated embodiment, the spiral groove 141 on the outer sidewall of the heating rod 140 is omitted, which promotes simplification of the manufacturing process of the heating rod 140 .

Roughly, the assembly process of the heating assembly 100 shown in FIG. 10 is as follows:

After inserting one end of the heating wire 150 into the air inlet 1231 , the heating wire 150 is spirally wound on the outer sidewall of the heating rod 140 , and then the other end of the heating wire 150 . is guided outward via the through hole 142 . The assembled heating wire 150 and the heating rod 140 are inserted into the second chamber 110b until the adjacent plate 144 is adjacent to the pipe body 110 . The guiding passage 11a is cooperatively formed by the heating wire 150 , the outer sidewall of the heating rod 140 , and the inner wall of the pipe body 110 .

A receiving hole is arranged on the heating pipe for receiving the tobacco product 20 . The receiving aperture has an inner diameter similar to the diameter of the tobacco product 20 for placing the tobacco product 20 into the receiving aperture. The heating pipe is connected to the pipe body 110 . For example, the heating pipe may be connected to the heating pipe body 110 by threading. A female screw may be additionally provided on the inner wall of the first chamber 110a, an external side wall of the heating pipe may be provided with a male screw, and the male screw may be screwed with the female screw.

In summary, the working process of the exemplified non-combustion heated smoking device 10 is as follows:

After turning on the power, the heating piece 130 and the heating wire 150 are switched to the heating operation state at the same time, the heating piece 130 is heated rapidly to reach the atomization temperature of the tobacco product 20 preferentially, the heating piece 130 is in direct contact with the tobacco product 20 so that the smoking devices 10 are converted to a usable state within a short time; Then, while the heating wire 150 continues to heat, the heating piece 130 stops working. Cool air enters the second chamber 110b from the outside via the air inlet 1231 . The cold air flows upward along the guiding passage 11a, wherein the guiding passage 11a is on the outer sidewall of the heating wire 150, the heating rod 140, and the inner wall of the pipe body 110. It is cooperatively formed by the heat wire 150 , the outer sidewall of the heating rod 140 , the spiral groove 141 and the inner wall of the pipe body 110 . The heating wire 150 heats the cold air flowing through the guiding passage 11a, and the heated air enters the first chamber 110a through the filter 120, and the pipe body ( The first chamber 110a is entered to heat and atomize the tobacco product 20 located within 110 .

According to the non-combustion heated smoking device 10 and its heating assembly 100 , the guiding passage 11a is formed by the spiral heating wire 150 , the outer sidewall of the heating rod 140 and the inner wall of the pipe body 110 . formed cooperatively, so that the guiding passage 11a is also spiral, and cold air enters the pipe body 110 via the air inlet 1231 and then flows along the spiral guiding passage 11a At this time, since the heating wire 150 can be heated quickly and the heating wire 150 heats the air inside the guiding passage 11a and the heating rod 140, cold air and the heating wire 150 and The contact time and contact area between the heating rods 140 are increased, so that the sucked cold air can be sufficiently heated, the cigarette is heated and atomized without burning, and the use efficiency of the tobacco product 20 is 50% or more , and the heating effect becomes more uniform. When not in use, no cold air enters the heating assembly 100 due to the suction action and therefore no heated airflow heats the tobacco product 20 , which reduces the loss of the tobacco product 20 . It can effectively reduce and encourage a relative increase in the effective number of inhalation.

The heating piece 130 is guided out of the first chamber 110a via a first conductive wire 133, and the heating rod 140 and the heating piece 130 are controlled by circuits independent of each other. and the heating rod 140 and the heating piece 130 are switched to a heating operation state at the same time after the power is turned on, and the heating piece 130 is heated more rapidly to preferentially the atomization temperature of the tobacco product 20 is reached, the heating piece 130 is in contact with the tobacco product 20 , so that the smoking devices 10 are converted to a usable state within a short time. Then, while the heating rod 140 continues heating, the heating piece 130 stops working, so that the cold air entering the pipe body 110 via the air inlet 1231 is the spiral or After flowing through the stepped guiding passage (11a) can be sufficiently heated, the heated air flows through the filter (120) into the first chamber (110a), the tobacco product (20) by radiation ) is continuously and uniformly heated, resulting in better and faster heating effect.

Referring to FIG. 11 , in the heating assembly 100 according to the third embodiment, the heating rod 140 is electrically coupled to the power source or the battery 30 via a conductive wire 500 and is inverted. generate heat in For example, the heating rod 140 may be a ceramic rod provided with a heating filament and an internal thermistor wire, and the heating filament and the thermistor are integrally formed with the ceramic rod. Obviously, in an alternative embodiment the heating rod 140 may be formed of a metal material or the like having better heating performance.

In the illustrated embodiment, the heating wire 150 may be omitted, and the spiral guiding element 400 is sleeved on the heating rod 140 so that the guiding passage 11a is connected to the guiding element ( 400 ), the outer sidewall of the heating rod and the inner wall of the pipe body 110 , cooperatively formed. After cold air enters the pipe body 110 through the air inlet 1231, it is guided along the guiding passage 11a (same as the direction indicated by the arrow in FIG. 11). For example, the guiding element 400 may have a smaller volume and the coil may have more springs, which may be heated quickly. The spring may be made of a heat-resistant and thermally conductive material.

Referring to FIG. 12 , in the heating assembly 100 according to the fourth embodiment, the heating rod 140 is electrically coupled to a power source or battery 30 via a conductive wire 500 and is inverted. generate heat A plurality of radially protruding convex rings 600 are provided on the outer sidewall of the heating rod 140 , and the plurality of convex rings 600 are spaced apart from each other in the axial direction of the heating rod 140 .

In particular in the embodiment shown in FIG. 6 , each convex annulus 600 defines a notch 610 , and notches 610 on two adjacent convex annulus 600 align the notch 610 of the heating rod 140 . located on different sides. For example, the notch 610 on the two adjacent convex annulus 600 is located on opposite sides of the heating rod 140 . Obviously, in an alternative embodiment the notch 610 on the two adjacent convex rings 600 may be located on the sides adjacent to each other. The space between each of the convex rings 600 is coupled through the notches 610 to form a stepped guiding passage 11a.

Moreover, the space between the two adjacent convex rings 600 may be connected by an opening disposed on the convex rings 600 . After the cold air enters the pipe body 110 through the air inlet 1231 , from the space between the two convex rings 600 adjacent to the bottom portion, through the notch 610 or the opening, two adjacent It gradually enters the space between the convex rings 600 , and then enters the space between the convex rings 600 adjacent to the upper part, and finally enters the first chamber 110a through the filter 120 . , the tobacco product 20 is heated and atomized to produce smoke (as indicated by the arrow in FIG. 12 ).

Referring to FIG. 13 , in the heating assembly 100 according to the fifth embodiment, the heating rod 140 is electrically coupled to the power source or the battery 30 via a conductive wire 500 and is inverted. generate heat The spiral guiding groove 141 is disposed directly on the outer sidewall of the heating rod 140 . Cold air enters the pipe body 110 through the air inlet 1231 and flows along the path of the guiding groove 141 , and the heating rod 140 heats the cold air.

The above-described embodiments are merely concrete implementations of the present invention, but are not intended to limit the protection scope of the present invention. It should be noted that any change or substitution easily made within the technical scope disclosed in the present invention by a person skilled in the art shall fall within the protection scope of the present invention. Therefore, the protection scope of the present invention should belong to the protection scope of the appended claims.

Claims (19)

A heating assembly comprising:
a pipe body defining an air inlet at an end thereof, wherein a filter is located in the pipe body, the pipe body being divided by the filter into a first chamber and a second chamber communicating with the first chamber;
A heating rod accommodated in the second chamber, wherein a heating space is formed between the heating rod and an inner wall of the pipe body, the heating space having a spiral or stepped guiding passage therein Forming a, the heating rod; and
a heating piece comprising first and second ends opposite each other;
The size of the second end is smaller than the size of the first end, the first end is connected to the filter, the second end is accommodated in the first chamber, the heating piece via a first conductive wire to be guided out of the first chamber,
wherein the heating rod and the heating piece are independently controlled by circuits independent of each other, wherein the heating piece ceases operation when the heating piece reaches a predetermined atomization temperature. The heating assembly of claim 1 , wherein the heating piece and the filter are integrally formed. The method according to claim 1 or 2, wherein the filter and the pipe body are integrally formed;
wherein the filter and the pipe body are separate structures. The heating assembly of claim 1 , wherein the first end of the heating piece extends through the filter and into the second chamber. The heating assembly of claim 1 , wherein a portion of the sidewall of the heating piece received within the first chamber is printed with heating circuitry. The method of claim 1 , wherein the heating piece has a thickness in the range of 0.35 mm to 0.6 mm;
wherein the heating piece is made of ceramic, zirconia or metal. The heating assembly of claim 1 , wherein the heating piece is connected to the first conductive wire via a brazing process. The method according to claim 1, further comprising a heating wire, wherein the heating wire is spirally wound on an outer sidewall of the heating rod, and the guiding passage is formed by the heating wire, the outer sidewall of the heating rod and the inner wall of the pipe body. A heating assembly formed cooperatively. 9. The heating rod according to claim 8, wherein the outer sidewall of the heating rod defines a spiral groove, the hot wire is spirally wound around the outer sidewall of the heating rod along the spiral groove, and the guiding passage comprises the hot wire; A heating assembly cooperatively defined by an outer sidewall of a heating bar, the helical groove and the inner wall of the pipe body. The method according to claim 9, wherein both ends of the heating wire are electrically coupled to a power source or a battery, respectively;
and the heating rod is electrically coupled to the power source or the battery via a conductive wire. 11. The heating rod according to claim 10, wherein: said heating rod defines through-holes extending through both ends of said heating rod along an axial direction thereof; one end of the heating wire extends into the pipe body via one end of the pipe body, and the other end of the heating wire extends from the end of the pipe body via the through hole to the outside of the pipe body. . 12. The heating rod according to claim 11, wherein one end of the heating rod defines a side hole on a side wall thereof, the side hole communicates with the through hole, and the other end of the heating wire passes through the side hole. and extending into the through hole. The heating assembly of claim 1 , wherein an outer wall of the heating rod defines a spiral guiding groove, the heating rod being electrically coupled to a power source or battery. According to claim 1, wherein the heating rod is electrically coupled to a power source or battery via a conductive wire, a spiral guiding element is sleeved on the heating rod, the guiding passage is the guiding element, A heating assembly cooperatively defined by an outer sidewall of a heating rod and an inner wall of the pipe body. The heating rod according to claim 1, wherein the heating rod is electrically coupled to a power source or a battery via a conductive wire, and an outer sidewall of the heating rod is provided with a plurality of radially projecting convex rings, wherein the plurality of convex rings comprises the spaced apart along the axial direction of the heating rod; and each convex annulus defines an opening or notch, wherein the opening or notches on two adjacent convex annulus are located on different sides of the heating rod. According to claim 1, further comprising an air inlet pipe having an inlet end and an outlet end, the side wall of the air inlet pipe is sealed, the outlet end communicates with the air inlet pipe, the inlet end has a one-way A heating assembly provided with an airflow sensor. The heating assembly according to claim 1, wherein the pipe body is made of an insulating and thermally conductive material, and a temperature sensor is provided on an outer sidewall of the pipe body. 2. The pipe body according to claim 1, wherein the sidewall of the pipe body defines a wiring hole, the first conductive wire is guided out of the first chamber via the wiring hole, and the wiring hole is tapered to prevent air leakage. ), the heating assembly. A heat-not-burn smoking device comprising a heating assembly according to claim 1 .

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