RU2789779C1 - Apparatus for recovering heat energy and contact-free electronic cigarette heater with air heating with said apparatus - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: group of inventions relates to an apparatus for recovering heat energy and a contact-free electronic cigarette heater with air heating with said apparatus. Apparatus for recovering heat energy includes a body of an aluminium oxide ceramic tube, forming an empty cavity configured to accommodate a heating element; a first cellular porous channel is located in the side wall of the body of the aluminium oxide ceramic tube, and the first cellular porous channel divides the body of the aluminium oxide ceramic tube into an outer wall and an inner wall. In the apparatus for recovering heat energy according to the invention, the side wall of the body of the aluminium oxide ceramic tube has a unique cellular porous structure; when the heating element placed in the formed empty cavity sinters the smoking product, the heat not acting on the smoking product is transferred to the body of the aluminium oxide ceramic tube.

EFFECT: since highly pure aluminium oxide ceramics with a relatively high heat conductivity coefficient are used for the body, part of the body of the aluminium oxide ceramic tube will be heated faster and further heat the air in the porous channel; when inhaling, the channel can recover heat and conserve energy.

14 cl, 5 dwg

Description

Technical field

The invention relates to the technical field of electronic cigarettes, in particular to a device for recovering thermal energy and a non-contact heater of electronic cigarettes with air heating.

Prior Art

A smoking product, such as cigarettes and cigars, burns tobacco during use and produces tobacco smoke. A burning cigarette contains many carcinogenic substances such as tar in its smoke, long-term inhalation of these substances can cause great harm to the human body. With the scientific and technological progress of science and technology and people's desire for a healthy lifestyle, a cigarette substitute has appeared, namely electronic cigarettes. In particular, providing a substitute for these types of products by producing products that release compounds without burning is one typical option for electronic cigarettes. Examples of such products are so-called non-combustion heating products, also called tobacco heating products or tobacco heating devices, which release compounds by heating a given material without burning it.

Currently on the market, existing non-combustion heating electronic cigarettes, their heating and sintering technology mainly uses the heat transfer method for heat transfer and heat exchange, the existing heating methods are plate heating (needle heating) and tube heating methods, for example, in CN201380044053.7 published "Smoking product used with internal heating elements", their heating method is plate heating method (needle heating), but this heating method has a higher temperature in the center, lower ambient temperature, the tobacco near the plate heater is completely charred, even burnt , and the surrounding tobacco is not yet charred, with great waste of tobacco; and for example, in CN201080053099.1, "Internal or external heater electronic heating smoking system" is published, its heating method is tube heating, and tube heating is that the part near the tube wall is more completely charred, and the center cannot be completely charred , if you raise the temperature, the cigarette paper will be burnt, which will affect the mouthfeel. Generalizations and conclusions that existing heating devices have technical defects such as uneven sintering, little smoke, poor mouthfeel and poor user experience, and after long-term use of electronic cigarettes, contaminants generated by inhaling will attach to products, cause an unpleasant odor.

The essence of the invention

This application is based on deep research and constant experimentation of the author on the following issues:

In related techniques, the contact heating and sintering technique mainly performs heat transfer and heat transfer exchange, that is, a heating conductor (eg, ceramic heating plate or needle) transfers the temperature to the sintered body (fuming body). The disadvantage of this heating method is mainly: 1. Poor thermal conductivity of the sintered body (fuming body) cannot completely transfer the temperature, resulting in uneven sintering inside and outside the sintered body; 2. There is a large difference in the spatial density of various types of sintered objects, when replacing various types of sintered objects, it is difficult to ensure their heating and sintering effect, it is generally necessary to use suitable sintered objects to obtain a good effect, so adaptability is poor. In general, existing heating devices have technical defects such as uneven sintering, little smoke, poor mouthfeel and poor user experience, these defects seriously limit further development, implementation and application in this field.

However, the heat loss of the ceramic heating cup/heating tube/heating pot type heater is very serious, and it is not good to use the heat emitted by the heater to the environment, poor heat dissipation will affect the tactile feeling when using, also accelerate the consumption of electronic cigarette lithium batteries.

Therefore, after a lot of research and experimentation, the present applicant has found that the puffing process itself is an air flow process, if the temperature of the air flowing into the smoking article is high, the hot air can directly play the role of sintering the smoking article, also because the hot air can relatively completely and uniformly penetrate and bake the entire tobacco of the smoking article with the puffing process, the problem of uneven heating can be effectively solved. Therefore, first heat the air, then use the hot air flow in the puffing process to sinter the smoking product, so that the heating is carried out, it will get the best overall heating effect.

But when applying the air heating example, it is first necessary to select a suitable heater to heat the air, and when the heater heats the air, room temperature air is required to enter the heater, the temperature of the air out of the heater is more than 300°C; Second, the general puff habit must be considered, that is, the temperature rise process must maintain about 20ml per second, and each puff is about 3 seconds, the heater needs a total heating efficiency of about 60ml of air.

In order to achieve the above effect, after a lot of experiments, the author came to the conclusion that when using a filament to heat the air, a higher filament temperature is required to heat the air only by the filament, and only when the temperature of the filament is higher than 600 ° C, can heat the flowing air to a temperature above 300°C, also if the air flow flows, the heating wire will cool rapidly, so that one puff will reduce the temperature of the filament by 200-300°C. Therefore, it is necessary to compensate for the power of the filament when puffing, otherwise it is difficult to achieve the effect of heating the air necessary to puff the cigarette, but when to compensate for the power by detecting the amount of air flow by the air flow sensor, due to the small contact area of the filament with air, this example Power compensation not only requires high power to achieve the desired heating effect, but there is also a problem of uneven temperature in all directions due to inaccurate air temperature and delayed compensation response after heating.

However, when heating the flowing air by raising the temperature of the filament to a temperature above 300°C, due to the increase in the temperature of the filament, the metal ions separated from the filament may mix with the flow of smoked air and enter the human body, causing harm to health. person.

Based on the above, after a lot of research, the present inventor has come to the conclusion that, when using the example of air heating to sinter a smoking article, the air heating heater requires a large heating area to reduce the temperature difference between the heater and the air, while the heater also requires a larger heat capacity to resist cooling after passing through the smoking air flow, and the heater also requires a higher thermal conductivity to shorten the preparation time for heating.

Therefore, based on many years of in-depth research on ceramics, the applicant found that the porous structure of honeycomb ceramics can obtain a large heating surface area, so that the heater has high air heating efficiency, at the same time, honeycomb ceramics of porous structure is more like a solid structure, has a higher heat capacity than ceramic tube of the same volume, further the thermal conductivity of the aluminum oxide material is more than 30W/m*K, it can achieve faster and more uniform heat transfer, as well as high thermal conductivity, thus the honeycomb ceramic porous structure heater can meet the sintering needs of the smoking product by heating the air .

The first object of the present invention is to provide a heat recovery device with heat recovery performance, long service life and small volume.

In order to achieve this, the heat recovery device shown in the first side embodiment of the present invention includes an alumina ceramic tube body, the alumina ceramic tube body defines an empty cavity to accommodate a heating element, a first honeycomb porous channel, also the first honeycomb porous channel separates the body of the alumina ceramic tube into an outer wall and an inner wall.

Additionally, the center of the body of the alumina ceramic tube defines an empty cavity.

Additionally, the body density of the alumina ceramic tube is not less than 3.86 g/cm ³ .

Additionally, the body of the alumina ceramic tube is a hollow cylindrical body with a circular or polygonal cross section.

Additionally, the first honeycomb porous channel are evenly spaced polygonal holes.

In particular, the wall thickness of both the outer wall and the inner wall is greater than the wall thickness of the first honeycomb porous channel.

At the same time, the wall thickness of the first honeycomb porous channel is 0.1-0.5 mm.

Additionally, the first honeycomb porous channel is a uniformly spaced round hole, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent round holes is 0.1-0.5mm.

Further, the body of the alumina ceramic tube is connected to the heating element by a low thermal conductivity tube located in the inner wall.

The heat energy recovery device according to an embodiment of the present invention, the side wall of the body of the alumina ceramic tube uses a unique honeycomb porous structure, when the heating element placed in the limited empty cavity sinters the smoking article, the heat that does not act on the smoking article will transfer heat to the alumina ceramic tube body, because the relative high thermal conductivity of the high purity alumina ceramic used for the alumina ceramic tube body, so the alumina ceramic tube body part will heat up faster, further heating the air in the porous channel. When puffed, the heated air will flow upward from the heating element, and normal temperature air will flow into the honeycomb porous channel of the alumina ceramic tube body, further remove heat from the alumina ceramic tube body, thereby performing heat recovery, saving energy.

The second purpose of the present invention is to provide a non-contact air heated electronic cigarette heater, it sinters evenly, does not pollute the product due to the direct contact of contaminants in the liquid or the smoke cartridge heater.

To achieve this object, the electronic cigarette heater of the contactless air-heated electronic cigarette heater shown in the embodiment on the second side of the present invention includes a ceramic heating element; the heat recovery device as described above, the heat recovery device defines an empty cavity to accommodate the heating element and the smoking article.

Further, the heating element includes a heater, a second honeycomb porous channel is located in the heater, a heating circuit is located on the heater to heat the air passing through the second honeycomb porous channel.

Additionally, the heating element includes a preheating tube and a baffle, a heater is located under the preheating tube, also a baffle is located between the preheating tube and the heater, and some guide holes are located on the baffle.

Further, the contactless air heating electronic cigarette heater also includes a sealing sleeve, the sealing sleeve is located on the inner wall of the heat recovery device, the heating element is located in the sealing sleeve, and the heating element is connected to the heat recovery device by the sealing sleeve.

Additionally, the heating element and the device for heat energy recovery are made of high purity alumina ceramics, their density is not less than 3.86 g/cm ³ .

Additionally, the first honeycomb porous channel and the second honeycomb porous channel are evenly spaced polygonal holes, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent holes is 0.1-0.5mm.

More specifically, the non-contact air heating electronic cigarette heater according to an embodiment of the present invention includes a heating element, a sealing sleeve, a heat recovery device, a first honeycomb porous channel is located in the side wall of the heat recovery device, the first honeycomb porous channel separates the heat recovery device energy on the outer wall and the inner wall; a sealing sleeve is located in the inner wall of the heat energy recovery device, a heating element is placed in the sealing sleeve, the heating element is connected to the heat energy recovery device by means of a sealing sleeve, a heater is located in the heating element; a heating circuit is located on the heater, a wire is located at the end of the heating circuit, a second honeycomb porous channel is located in the heater.

Next, the heating element from top to bottom in turn as pre-heating tube, baffle and heater, there are some guiding holes on the baffle.

Further, the materials of the heating printed circuit include, but are not limited to, silver, tungsten, MoMn.

Further wire materials include but are not limited to silver, copper and nickels.

The non-contact air-heating electronic cigarette heater according to an embodiment of the present invention heats air with a heating element so that the heated air flow evenly bakes tobacco to increase the volume of smoke. At the same time, the heating element and the heat recovery device are made of high purity alumina ceramic, high purity alumina ceramic has high density, almost no pores in microstructure, pollutants in the liquid can not penetrate into them, can not leave dirt and bad smell on the surface , also the method of heating the air provides protection of the device from contamination due to the lack of contact with the smoke cartridge.

Description of attached figures

Figure 1 is a diagram of the structure of a device for recovering heat energy according to an embodiment of the present invention;

Figure 2 is a diagram of the structure of a device for recovering heat energy according to another embodiment of the present invention;

Figure 3 is a diagram of the structure of a non-contact heater of electronic cigarettes with air heating according to an embodiment of the present invention;

Figure 4 - Diagram of the structure of the heater according to an embodiment of the present invention;

Figure 5 - Diagram of the structure of the deflector according to an embodiment of the present invention;

Detailed Implementation Methods

In order to make the objectives, technical solutions and advantages of the method for carrying out the present invention more clear, in conjunction with the attached figures in the method for carrying out the present invention, the technical solutions in the method for carrying out the present invention will be clearly and completely described below, while the described method of carrying out is only one of the ways implementation of the present invention, and not all methods of implementation. Based on the method of carrying out the present invention, all other methods of carrying out obtained by an ordinary technician in this field without creative work fall within the protection scope of the present invention. Therefore, the following detailed description of exemplary embodiments of the present invention, presented in the accompanying figures, is not used to limit the scope of the claimed invention, but only represents the selected mode for carrying out the present invention. Based on the method of carrying out the present invention, all other methods of carrying out obtained by an ordinary technician in this field without creative work fall within the protection scope of the present invention.

In describing the present invention, it should be explained that the ratio of orientations or positions that indicate the terms "top", "bottom", "inner", "outer", "front end", "rear end", "both ends", "one end", "other end" and others based on the accompanying figures, only for the convenience of describing the present invention and simplifying the description, and do not indicate or imply that the above device or element must have a specific orientation, composition of a specific orientation and operation, cannot be understood as a limitation of the present invention. In addition, the terms "first" and "second" are only used to describe the purpose, and cannot be understood as indicating or implying relative importance.

In the description of the present invention, unless otherwise clearly defined and limited, the terms "installation", "installed", "connection" and so on should be understood in a broad sense, for example, "connection" can be understood as a fixed connection, also can be understood as a removable connection, or an integral connection; can be understood as a mechanical connection, or can be understood as an electrical connection; can be understood as a direct connection, can also be understood as an indirect connection through an intermediate medium, can be understood as an internal connection between two components. One of ordinary skill in the art can understand the specific meanings of the above terms in the present invention according to specific situations.

The heat recovery device and the contactless air-heating electronic cigarette heater with the heat recovery device are described below as embodiments of the present invention based on the accompanying figures.

As shown in Figures 1 and 2, the heat energy recovery apparatus of an embodiment of the present invention includes an alumina ceramic tube body 1, the alumina ceramic tube body 1 defines an empty cavity 5 to house a heating element 6 in a side wall of the alumina ceramic tube body 1, the first honeycomb porous channel 2 is located, and the first honeycomb porous channel 2 also separates the body 1 of the alumina ceramic tube into the outer wall 3 and the inner wall 4.

Additionally, the center of the alumina ceramic tube body 1 defines an empty cavity 5 to accommodate a heating element 6, such as a ceramic heater.

Additionally, as one embodiment, the density of the body of the alumina ceramic tube is not less than 3.86 g/cm ³ .

Additionally, the body of the alumina ceramic tube is a hollow cylindrical body with a circular or polygonal cross section.

According to an exemplary embodiment of the present invention, the first honeycomb porous channel 2 is a uniformly spaced polygonal opening. In other embodiments of the present invention, the first honeycomb porous channel 2 is also a uniformly spaced round hole.

Further, the wall thickness of both the outer wall 3 and the inner wall 4 is greater than the wall thickness of the first honeycomb porous channel 2.

More specifically, the wall thickness of the first honeycomb porous channel is 0.1-0.5 mm.

According to another embodiment of the present invention, when the first honeycomb porous channel is a uniformly spaced round hole 2, the hole diameter range is 0.1-2 mm, the minimum distance between two adjacent round holes is 0.1-0.5 mm.

More specifically, as shown in Figure 1-2, the heat energy recovery device proposed by the exemplary embodiment of the present invention includes an alumina ceramic tube body 1, a heating element 6 is located in the center of the alumina ceramic tube body 1, and a heating element 6 is located in the side wall of the alumina ceramic tube body 1. the first honeycomb porous channel 2, also the first honeycomb porous channel 2 separates the body of the alumina ceramic tube into an outer wall 3 and an inner wall 4; in the empty cavity 5 of the center of the body 1 of the alumina ceramic tube is a heating element 6; the density of the housing 1 alumina ceramic tube is not less than 3.86 g/cm ³ ; the body of the alumina ceramic tube 1 is a hollow cylindrical body with a circular cross section; the first honeycomb porous channel 2 is formed by evenly spaced polygonal holes; the wall thickness of both the outer wall 3 and the inner wall 4 is greater than the wall thickness of the first honeycomb porous channel 2, thus can slow down the rate of heat transfer from the central heat source to the outside; the wall thickness of the first honeycomb porous channel 2 is 0.2 mm; at the same time, the body of the alumina ceramic tube 1 is connected to the heating element 6 by a low thermal conductivity tube 7 located in the inner wall 4; the low thermal conductivity tube 7 includes, but is not limited to, mullite, cordierite, and other materials.

The purity of the case of the alumina honeycomb ceramic 1 according to the example of the present invention exceeds 99%, so that the surface density of the honeycomb ceramics is very high, it can effectively prevent the adsorption of dust particles and protect against bad smell.

The side wall of the alumina ceramic tube body 1 uses a unique honeycomb porous structure, when the heating element 6 in the center sinters the smoking article, the heat that does not affect the smoking article will be transferred to the alumina ceramic tube body 1, due to the fact that the relative high thermal conductivity coefficient of the high purity alumina ceramic used for the alumina ceramic tube body 1, so the alumina ceramic tube body part 1 will heat up faster and heat the air in the porous passage. When puffed, the heated air will flow upward from the heating element 6, and normal temperature air flows into the first honeycomb porous channel 2 of the alumina ceramic tube body 1, further removes heat from the alumina ceramic tube body 1, thereby performing heat recovery and saving energy. The low thermal conductivity tube 7 is used to fix the heating element 6, it has a certain role of keeping heat in the center, preventing rapid heat loss to the environment, and reducing energy consumption. Alumina ceramic with stable structure, high reliability, long service life.

As shown in Figure 2 and Figure 3, the contactless air-heating electronic cigarette heater of the embodiment of the present invention includes a heating element 6 and a heat recovery device 8 described in the above embodiment.

In particular, the heat recovery device 8 defines an empty cavity 5 to accommodate a heating element 6 and a smoking article (not shown in the figure).

Further, as shown in FIG. 3, in the exemplary embodiment of the present invention, the heating element 6 includes a heater 13. As shown in FIG. second honeycomb porous channel 133.

However, as shown in figures 3 and 5, the heating element 6 includes a preheat tube 11 and a baffle 12, a heater 13 is located under the preheat tube 11, and a baffle 12 is located between the preheat tube 11 and the heater 13, on the deflector 12 has several guide holes 121.

In the exemplary embodiment of the present invention, when the smoker wants to smoke, he inserts the smoke cartridge into the preheating tube 11 to prevent the smoke cartridge from falling off, after turning on the power, the heating circuit 131 starts to heat up. Due to the fact that active ingredients such as nicotine can be sintered at a temperature of 280°C-320°C and thereby generate smoke for a puff, the smoke cartridge must be preheated. After reaching the temperature of the preheat tube 11 and deflector 12 to 200°C, preheating is completed, in connection with the completion of preheating, at the first and second puffs, namely the first heating, increasing the temperature of the smoke cartridge from 200°C to 320°C faster at room temperature. Thus, it is possible to provide a larger volume of smoke of the first and second puffs. For rapid heating, the heater 13 has a honeycomb porous channel 133, also this honeycomb porous channel is a uniformly spaced round hole or a polygonal hole, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent holes is 0.1-0 .5 mm, the sweep area is large, so the heating efficiency of the air is very high, and the hot air flows out from the honeycomb center, does not contact the heating circuit 131, and does not cause pollution. Because the preheating tube 11, the heater 13, and the baffle 12 are made of high purity alumina ceramics, which have good electrical insulation, high strength and good thermal conductivity, the ceramic heater 13 does not leak current when heated, the preheating tube 11 and baffle 12 also quickly raise the temperature due to the good thermal conductivity of high purity alumina ceramics; when puffing, the air flow through the ceramic heater 13 is heated to a temperature of 320 ° C, and then passes through the guide holes 121 on the deflector 12 for further homogenization and separation of the flow, more uniform entry of the smoke cartridge into the heated tobacco to increase the volume of smoke, to provide a good feeling of inhaling in the mouth, the best user experience. During the puffing process, some liquid contaminants emitted by the smoke cartridge will inevitably remain in the device, due to the fact that the high purity alumina ceramic has a high density, almost no pores in microstructure, the contaminants in the liquid cannot penetrate into them, cannot leave dirt and unpleasant odors on the surface.

According to the exemplary embodiment of the present invention, as shown in Figure 3, the above non-contact air-heating electronic cigarette heater also includes a sealing sleeve 9, a sealing sleeve 9 is located on the inner wall of the heat recovery device 8, a heating element 6 is located in the sealing sleeve 9, and the heating element 6 is connected to the heat energy recovery device 8 by means of a sealing sleeve 9.

In an exemplary embodiment of the present invention, the heating element 6 and the heat recovery device 8 are made of high purity alumina ceramics with a density of at least 3.86 g/cm ³ .

More specifically, as an exemplary embodiment, the first honeycomb porous channel 2 and the second honeycomb porous channel 133 are evenly spaced polygonal holes, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent holes is 0.1-0.5mm.

As an exemplary embodiment of the present invention, with reference to Figures 1 to 5, an air-heating contactless electronic cigarette heater includes a heating element 6, a sealing sleeve 9, and a heat recovery device 8, a first honeycomb is located in the side wall of the heat recovery device 8. porous channel 2, the first honeycomb porous channel 2 separates the heat recovery device 8 into an outer wall 3 and an inner wall 4; a sealing sleeve 9 is located in the inner wall 4 of the heat energy recovery device 8, a heating element 6 is put on in the sealing sleeve 9, the heating element 6 is connected to the heat energy recovery device 8 by means of a sealing sleeve 9, a heater 13 is located in the heating element 6, on the heating circuit 131 is located in the heater 13, the wire 132 is located at the end of the heating circuit 131, the second honeycomb porous channel 133 is located in the heater 13.

Further, the heating element 6 comprises, from top to bottom, a preheating pipe 11, a baffle 12, and a heater 13 in turn, and a plurality of guide holes 121 are located on the baffle 12.

Further, the heating element 6 and the heat energy recovery device 8 are made of high purity alumina ceramics, and their density is not less than 3.86 g/cm ³ .

Further, the first honeycomb porous channel 2 and the second honeycomb porous channel 133 are evenly spaced square holes or other polygonal holes, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent holes is 0.1-0.5mm.

Further, the printed materials of the heating circuit 131 include, but are not limited to, silver, tungsten, MoMn.

Further materials of wire 132 include, but are not limited to, silver, copper, and nickel.

In this embodiment, as shown in Figure 3, in the side wall of the heat recovery device 8 is the first honeycomb porous channel 2, the first honeycomb porous channel 2 separates the heat recovery device into the outer wall 3 and the inner wall 4; a sealing sleeve 9 is located in the inner wall 4 of the heat energy recovery device 8, a heating element 6 is placed in the sealing sleeve 9, the heating element 6 is connected to the heat energy recovery device 8 by means of a sealing sleeve 9; the heating element 6 comprises from top to bottom in turn a preheating tube 11, a baffle 12 and a heater 13, as shown in figure 4, a heating circuit 131 is located on the heater 13, a wire 132 is located at the end of the heating circuit 131, a second honeycomb porous is located in the heater 13 channel 133. When the smoker wants to smoke, he inserts the smoke cartridge into the preheating tube 11 to prevent the smoke cartridge from falling off, after turning on the power, the heating circuit 131 starts to heat up. Due to the fact that active ingredients such as nicotine can be sintered at a temperature of 280°C-320°C and thereby generate smoke for a puff, the smoke cartridge must be preheated. After reaching the temperature of the preheat tube 11 and deflector 12 to 200°C, preheating is completed, in connection with the completion of preheating, at the first and second puffs, namely the first heating, increasing the temperature of the smoke cartridge from 200°C to 320°C faster at room temperature. Thus, it is possible to provide a larger volume of smoke of the first and second puffs. For rapid heating, the heater 13 has a second honeycomb porous channel 133, also this honeycomb porous channel is a uniformly spaced round hole or other polygonal holes, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent holes is 0.1 -0.5mm, the sweep area is large, so the heating efficiency of the air is very high, also the hot air flows out from the honeycomb center, does not contact the heating circuit 131, and does not cause pollution. At the same time, the heating element 6 and the heat recovery device 8 are made of high purity alumina ceramic, which has good electrical insulation, high strength and good thermal conductivity, so the ceramic heater 13 does not leak current when heated, the preheating tube 11 and the deflector 12 are also fast increase the temperature due to the good thermal conductivity of high purity alumina ceramics, and soon you can smoke tobacco; when puffed, the air flow through the ceramic heater 13 is heated to a temperature of 320 ° C, and then passes through the guide holes 121 on the deflector 12 for further homogenization and flow separation, more uniform entry of the smoke cartridge into the heating tobacco to increase the volume of smoke during the heating process, all the heat that does not affect the smoke cartridge is transferred to the inner wall 4 of the heat recovery device 8, in which the sealing sleeve 9 is located, the heating element 6 is put on the sealing sleeve 9, the heat that is generated by the heating element 6 and does not affect the smoke cartridge is transferred into the first honeycomb porous channel 2, this honeycomb porous channel is a uniformly spaced square hole or other polygonal hole, the hole diameter range is 0.1-2mm, the minimum distance between two adjacent holes is 0.1-0.5mm, the sweep area large, therefore effective The heating capacity of the air is very high, so it plays the role of thermal insulation, reduces the heating time to save energy. When puffed, heated air flows out into the second honeycomb porous passage 133, and the air flows into the heat recovery device 8, further removes heat from the first honeycomb porous passage 2, thereby performing heat recovery. In particular, the sealing sleeve 9 plays the role of a seal between the heat recovery device 8 and the heating element 6 to prevent hot air from flowing to other places. During the tightening process, some liquid contaminants emitted by the smoke cartridge inevitably remain in the device, due to the fact that high purity alumina ceramic has a high density, its density is not less than 3.86 g/cm ³ , it has almost no pores in microstructure, contaminants in the liquid cannot penetrate them, cannot leave dirt and odor on the surface.

Although the embodiments of the present invention have been indicated and described above, it can be understood that the above embodiments cannot be understood as limiting the present invention, and a person of ordinary skill in the art may change, amend, replace and modify the above embodiments.

Claims (14)

1. A device for recuperation of thermal energy, containing a body of alumina ceramic tube, characterized in that the empty cavity formed by the body of alumina ceramic tube is configured to accommodate a heating element, while in the side wall of the body of alumina ceramic tube there is a first honeycomb porous channel separating alumina ceramic tube body on the outer wall and inner wall. 2. A device for recovering heat energy according to claim 1, characterized in that the center of the body of the alumina ceramic tube limits the empty cavity. 3. The device for heat energy recovery according to claim 1, characterized in that the density of the body of the alumina ceramic tube is not less than 3.86 g/cm ³ . 4. The device for heat energy recovery according to claim 1, characterized in that the body of the alumina ceramic tube is a hollow cylindrical body with a round or polygonal cross section. 5. The device for recuperation of thermal energy according to claim 1, characterized in that the first honeycomb porous channel is formed by evenly spaced polygonal holes. 6. The device for heat energy recovery according to claim 5, characterized in that the thickness of the outer wall and the inner wall of the housing is greater than the wall thickness of the first honeycomb porous channel. 7. A device for heat energy recovery according to claim 5, characterized in that the wall thickness of the first honeycomb porous channel is 0.1-0.5 mm. 8. The device for heat energy recovery according to claim 1, characterized in that the first honeycomb porous channel is formed by evenly spaced round holes with a diameter of 0.1-2 mm, while the minimum distance between two adjacent round holes is 0.1-0.5 mm. 9. A non-contact heater of electronic cigarettes with air heating, containing a heating element and a device for recovering thermal energy according to paragraphs. 1-8, characterized in that the empty cavity formed by the heat energy recovery device is configured to accommodate a heating element and a smoking product. 10. Contactless heater of electronic cigarettes with air heating according to claim 9, characterized in that the heating element includes a heater with a second honeycomb porous channel placed in it, while a heating circuit is located on the heater for heating air passing through the second honeycomb porous channel. 11. A non-contact air heated electronic cigarette heater according to claim 10, characterized in that the heater includes a preheat tube and a baffle, wherein the heater is located under the preheat tube, and the baffle is located between the preheat tube and the heater and is made with guide holes. 12. Contactless heater of electronic cigarettes with air heating according to paragraphs. 9-11, characterized in that it additionally includes a sealing sleeve located on the inner wall of the device for recovering heat energy, while the heating element is located in the sealing sleeve and connected to the device for recovering heat energy using a sealing sleeve. 13. A non-contact heater of electronic cigarettes with air heating according to claim 9, characterized in that the heating element and the device for recovering thermal energy are made of high purity alumina ceramics with a density of at least 3.86 g/cm ³ . 14. A non-contact heater of electronic cigarettes with air heating according to claim 10, characterized in that the first honeycomb porous channel and the second honeycomb porous channel are formed by evenly spaced polygonal holes with a diameter of 0.1-2 mm, while the minimum distance between two adjacent holes is 0 .1-0.5 mm.

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