A heat-not-burn device

The heating and non-combustible device, which automatically opens the lid by rotating the connecting component, solves the problem of burns from high temperatures in the heating chamber and improves safety during use.

CN224386759UActive Publication Date: 2026-06-23HG INNOVATION LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HG INNOVATION LTD
Filing Date
2025-04-28
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

When changing the heat-not-burning product in a heat-not-burning device, the high-temperature heating chamber may cause burns to the user.

Method used

An automatic opening heating non-combustible device was designed. By rotating the connecting component, the closed body is rotated to the open position on the side parallel to the main unit, realizing automatic opening and avoiding user contact with the high-temperature heating chamber.

Benefits of technology

This reduces the risk of users being burned when changing heated non-combustible products and improves the safety of the device.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224386759U_ABST
    Figure CN224386759U_ABST
Patent Text Reader

Abstract

The application discloses a heating non-combustion device, which comprises a main machine, a heating assembly, a closure body, a rotary connecting assembly and a stop release assembly. One side of the main machine is provided with a containing groove. The heating assembly is arranged in the containing groove and is provided with a heating cavity. The closure body is rotatable relative to the main machine in a plane parallel to the side of the main machine provided with the containing groove to an open position or a covering position through the rotary connecting assembly. The closure body is provided with a stop portion. The stop release assembly is in a stop state and stops at the stop portion to limit the closure body to the covering position. The stop release assembly is in a release state and releases the stop portion to enable the closure body to rotate to the open position. Through the operation of the stop release assembly, the closure body is released from the limitation and can be in the open position under the action of the rotary connecting assembly, that is, the heating non-combustion product can naturally fall in an inverted mode, the user's hand does not need to contact the cover body all the time, the risk of scalding is avoided, and the safety is improved.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application relates to the field of aerosol generation technology, specifically to a heating non-combustible device. Background Technology

[0002] The heating chamber of the heated non-combustible device contains replaceable heated non-combustible products. The heating element within the chamber heats these products to generate an aerosol that the user can inhale. After a period of use, the heated non-combustible products need to be replaced. Because heated non-combustible devices typically generate temperatures of 200°C to 300°C or even higher to heat the products, both the heated products and the heating chamber will be very hot. If a user comes into contact with the high-temperature heating chamber, they may suffer burns. Utility Model Content

[0003] This application aims to provide a heat-not-burning device, the main purpose of which is to provide an automatic opening heat-not-burning device that removes high-temperature heat-not-burning products in an inverted manner to avoid burns.

[0004] This application provides a heating non-combustible device, comprising:

[0005] The host computer has a receiving slot on one side;

[0006] A heating assembly is disposed in the receiving groove, the heating assembly having a heating chamber for accommodating a heated non-combustible product;

[0007] A closed body, wherein the closed body is provided with an aerosol outflow channel;

[0008] A rotating connection assembly is disposed between the enclosure and the main unit. The enclosure can rotate relative to the main unit in a plane parallel to the side of the main unit where the receiving groove is provided, to an open position or a covered position. In the covered position, the enclosure covers the heating cavity; in the open position, the enclosure opens the heating cavity.

[0009] A stop release assembly is disposed on the host unit. The closure body has a stop portion. The stop release assembly has a stop state and a release state. In the stop state, the stop release assembly stops at the stop portion to restrict the closure body from being in the covered position relative to the host unit. In the release state, the stop release assembly releases the stop portion to allow the closure body to rotate relative to the host unit to the open position via the rotary connection assembly.

[0010] In some embodiments, the rotary connection assembly includes a rotary shaft and a rotary drive. The rotary shaft is disposed on the host in a direction parallel to the axis of the heating chamber. The enclosure is rotatably connected to the host via the rotary shaft, and the enclosure can rotate relative to the host about the axis of the rotary shaft. The rotary drive is installed between the enclosure and the host, and the rotary drive is used to drive the enclosure to rotate relative to the host to the open position when the stop release assembly is in the released state.

[0011] In some embodiments, the rotary drive includes a torsion spring sleeved on the rotary shaft, the enclosure has a first slot, the host has a second slot, the first free end of the torsion spring is engaged with the first slot of the enclosure, and the second free end of the torsion spring is engaged with the second slot of the host.

[0012] In some embodiments, the closure body is provided with a limiting member on the side facing the host, and the host body is provided with a limiting mating part on the side where the receiving groove is located. The limiting member and the limiting mating part cooperate with each other to limit the angle of rotation of the closure body relative to the host when the closure body rotates relative to the host in a plane parallel to the side of the host where the receiving groove is located.

[0013] In some embodiments, the enclosure is further provided with a nozzle, the nozzle having a through-hole that communicates with the aerosol outflow channel, and the side wall of the nozzle having an air inlet.

[0014] In some embodiments, the stop-release assembly includes a blocking member that can be in a stop state and a release state. The blocking member is connected to the host, and the stop portion is a slot disposed in the enclosure. In the stop state, the blocking member is engaged with the slot. In the release state, the blocking member moves away from the enclosure and disengages from the slot.

[0015] In some embodiments, the stop release assembly further includes a release member, the main unit has a through hole, the release member is slidably inserted in the through hole between the stop position and the release position, and the blocking member is connected to the release member; in the stop position, the release member drives the blocking member to engage with the slot; in the release position, the release member drives the blocking member to disengage from the slot.

[0016] In some embodiments, the stop release assembly further includes an elastic reset member, the host is provided with a limiting member inside, the elastic reset member is disposed between the limiting member and the blocking member, and the elastic reset member is used to apply an elastic force away from the limiting member to the blocking member so as to keep the blocking member engaged in the slot when the release member is in the stop position.

[0017] In some embodiments, the release member is further provided with a protrusion, the protrusion being located in the portion of the release member placed inside the host, the protrusion engaging with the inner wall of the host to restrict the release member from disengaging from the through hole; the portion of the release member placed outside the host is further provided with a pressing portion, the pressing portion being pressed to cause the release member to drive the blocking member to slide from the stop position to the release position.

[0018] In some embodiments, the blocking member includes a blocking portion, a first connecting portion, and a second connecting portion. The first connecting portion is disposed between the blocking portion and the second connecting portion, and the second connecting portion abuts against the releasing member. The host has a rotating shaft inside, and the connection between the first connecting portion and the blocking portion is rotatably connected to the rotating shaft. The blocking portion and the first connecting portion have a first included angle, and the first connecting portion and the second connecting portion have a second included angle. The blocking member rotates around the rotating shaft in a first rotation direction or a second rotation direction to make the blocking portion engage with or disengage from the slot.

[0019] According to the heated non-combustible device in the above embodiments, by operating the stop release component, the stop release component releases the stop part, and the closure body can rotate relative to the main unit in a plane parallel to the receiving groove on the side of the main unit under the power provided by the rotating connecting component, to the covered position. During the rotation of the closure body, the user only needs to operate the stop release component, without needing to operate the closure body itself. The closure body is in an open state under the action of the rotating connecting component. Thus, when the heated non-combustible product used in the heating chamber is inverted and falls naturally, the user's hands do not need to touch the closure body, greatly reducing the risk of burns from the falling heated non-combustible product. This improves the safety of using this heated non-combustible device. Attached Figure Description

[0020] Figure 1 A schematic diagram of the heating non-combustible device provided in this application;

[0021] Figure 2 A perspective view of the heating non-combustible device provided in this application;

[0022] Figure 3 A schematic diagram showing the opening of the cover in the heated non-combustible device provided in this application;

[0023] Figure 4 Cross-section of the heating non-combustible device provided in this application Figure 1 ;

[0024] Figure 5 Exploded view of the heating non-combustible device provided in this application;

[0025] Figure 6 Cross-section of the heating non-combustible device provided in this application Figure 2 ;

[0026] Figure 7 Cross-section of the heating non-combustible device provided in this application Figure 3 ;

[0027] Figure 8 A perspective view of the cover of the heating non-combustible device provided in this application;

[0028] Figure 9 A perspective view of the blocking member in the stop release assembly of the heated non-combustible device provided in this application;

[0029] Figure 10 This is a schematic diagram showing the cooperation between the heating component and the nozzle in the heated non-combustible device provided in this application.

[0030] Explanation of reference numerals in the attached figures:

[0031] Main unit 10, receiving groove 11, through hole 12, second slot 13, limiting mating part 14, screw hole 15, limiting part 16, rotating shaft 17;

[0032] Enclosed body 20, stop part 21, slot 211, first slot 22, limiting member 23, first shaft hole 24;

[0033] Rotary connecting assembly 30, rotating shaft 31, rotating drive component 32, torsion spring 321, first free end 3211, second free end 3212, protrusion 33;

[0034] Stop release assembly 40, blocking member 41, blocking part 411, first connecting part 412, second connecting part 413, second shaft hole 414, release member 42, limiting protrusion 421, pressing part 422;

[0035] Heating component 50, heating cup 51, heating chamber 510, opening 5101, second air inlet channel 511, air outlet 512, air gathering block 513, heat exchange core 52, heat exchange hole 521, heating chamber 53, air collecting plate 54, air collecting hole 541, first one-way valve 55, second one-way valve 56.

[0036] The nozzle component 60, the nozzle channel 601, the aerosol outlet channel 610, the air inlet 611, the first air inlet channel 612, the variable diameter tube 62, the first mixing chamber 621, the acceleration chamber 622, the second mixing chamber 623, and the extension 63. Detailed Implementation

[0037] The present application will now be described in further detail with reference to the accompanying drawings and specific embodiments. Similar elements in different embodiments are referred to by related similar element reference numerals. In the following embodiments, many details are described to facilitate a better understanding of the present application. However, those skilled in the art will readily recognize that some features may be omitted in different situations, or may be replaced by other elements, materials, or methods. In some cases, certain operations related to the present application are not shown or described in the specification. This is to avoid obscuring the core parts of the present application with excessive description. For those skilled in the art, detailed description of these related operations is not necessary; they can fully understand the related operations based on the description in the specification and general technical knowledge in the art.

[0038] Furthermore, the features, operations, or characteristics described in the specification can be combined in any suitable manner to form various embodiments. At the same time, the steps or actions in the method description can be rearranged or adjusted in a manner obvious to those skilled in the art. Therefore, the various orders in the specification and drawings are only for the clear description of a particular embodiment and do not imply a necessary order, unless otherwise stated that a particular order must be followed.

[0039] The serial numbers assigned to components in this document, such as "first" and "second," are used only to distinguish the described objects and have no sequential or technical meaning. The terms "connection" and "linkage" used in this application, unless otherwise specified, include both direct and indirect connections (linkages).

[0040] Heated non-combustible devices use a heating element to heat a heated product placed in a heating chamber via a hot airflow. This heats the product, causing it to generate an edible aerosol. The heated non-combustible product typically consists only of a matrix, usually formed by die-casting a mixture of tobacco powder or other plant powders with a certain proportion of polyols, flavorings, and binders. The product is usually porous. Upon heating, the tobacco powder or plant powders, polyols, and flavorings volatilize, generating aerosols that cause the product to collapse, resulting in a reduction in its overall volume. When replacing the heated non-combustible product, the user manually opens the lid and pours the product out in an inverted position, keeping the lid open during this process. Because the heated product is heated at a high temperature and shrinks in volume after heating, there is a high risk of burns to the user's hands during the fall.

[0041] To address the aforementioned issues, this application provides a heated non-combustible device that allows the lid to rotate relative to the main unit in an open position on a plane parallel to the receiving groove on the main unit via a rotating connecting assembly. This enables automatic lid opening and automatically keeps the lid in the open state to avoid the risk of burns to the user.

[0042] See Figures 1-7 As shown, the heated non-combustible device provided in this application includes a main unit 10, a closed body 20, a rotary connection assembly 30, a stop release assembly 40, and a heating assembly 50.

[0043] The main unit 10 is the main structure of this heating non-combustion device. A receiving groove 11 is provided on one side of the main unit 10, which is used to receive the heating component 50.

[0044] The host 10 can be an integral block-shaped cuboid structure, and the receiving groove 11 is formed by setting a sink on one side. Figures 3-7 To better illustrate the internal structure of the host 10, the host 10 is depicted as a shell. Figures 3-7 The specific form of the host 10 is not limited as shown. In a preferred embodiment, the host 10 is a closed hollow cuboid structure, with one side being the top surface of the cuboid, and a recessed groove forming a receiving groove 11 is provided on this surface. Of course, other structures such as a power supply unit can also be provided inside the host 10 to provide the electrical energy required for heating the heating component 50.

[0045] The heating assembly 50 has a heating chamber 510 for containing a non-combustible product. The heating assembly 50 is used to heat the non-combustible product contained in the heating chamber 510 in a non-combustible manner. Specifically, the non-combustible product can be heated by a hot airflow through aerobic heating or anaerobic heating to generate an aerosol.

[0046] To facilitate the placement of heat-resistant non-combustible products into the heating chamber 510, the inner cavity of the heating chamber 510 is typically groove-shaped, with its opening flush with the surface of the main unit 10 on the side where the receiving groove 11 is located.

[0047] The enclosure 20 is provided with an aerosol outlet channel 610. The enclosure 20 is rotatable relative to the main unit 10 in a plane parallel to the side where the receiving groove 11 is provided on the main unit 10, and can be rotated to an open position or a covered position. When the enclosure 20 is rotated to the open position, the enclosure 20 opens the heating chamber 510. At this time, a heat-resistant non-combustible product can be placed into the heating chamber 510, or a heat-resistant non-combustible product can be removed from the heating chamber 510. When the enclosure 20 is rotated to the covered position, the enclosure 20 covers the heating chamber 510, and the aerosol outlet channel 610 is connected to the heating chamber 510. The aerosol generated by the heating component 50 heating the heat-resistant non-combustible product in the heating chamber 510 can be output through the aerosol outlet channel 610.

[0048] In order for the enclosure 20 to cover the heating cavity 510, the enclosure 20 is preferably a plate-shaped structure, and its bottom surface faces the side of the host 10 where the receiving groove 11 is provided when it is in the covered position.

[0049] Of course, in some embodiments, a sealing ring can also be provided on the bottom surface of the enclosure 20 or on one side surface of the host 10 where the receiving groove 11 is provided, so as to seal the bottom surface of the enclosure 20 and the one side surface of the host 10 where the receiving groove 11 is provided, thereby preventing aerosol leakage.

[0050] The rotating connection assembly 30 is disposed between the enclosure 20 and the host 10. The enclosure 20 can rotate relative to the host 10 to an open position or a covered position in a plane parallel to the side of the host 10 where the receiving groove 11 is provided, through the rotating connection assembly 30. The rotating connection assembly 30 provides power for the rotation of the enclosure 20 relative to the host 10 in a plane parallel to the side of the host 10 where the receiving groove 11 is provided.

[0051] like Figures 6-8As shown, a stop release assembly 40 is disposed on the main unit 10, and the closure 20 is provided with a stop portion 21. The stop release assembly 40 has a stop state and a release state. When the stop release assembly 40 is in the stop state, the stop release assembly 40 stops at the stop portion 21 to restrict the closure 20 from being in a covered position relative to the main unit 10, that is, to restrict the closure 20 from rotating relative to the main unit 10 in a plane parallel to the side of the main unit 10 where the receiving groove 11 is provided to the covered position. When the stop release assembly 40 is in the release state, the stop release assembly 40 releases the stop portion 21, allowing the closure 20 to rotate relative to the main unit 10 in a plane parallel to the side of the main unit 10 where the receiving groove 11 is provided to the open position via the rotary connecting assembly 30.

[0052] It should be noted that the process of rotating the closed body 20 relative to the host 10 to the open position can be achieved manually or automatically, depending on the specific structure of the rotating connection component 30.

[0053] In practical applications, a heat-resistant non-combustible product is placed in the heating chamber 510. The user operates the closure 20 to the covered position, and the stop release assembly 40 is in a stopped state, engaging with the stop part 21. The heating assembly 50 heats the heat-resistant non-combustible product in the heating chamber 510 to generate aerosol, which is then output through the aerosol outlet channel 610. When it is necessary to replace the heat-resistant non-combustible product, the stop release assembly 40 is operated to release the stop part 21. The closure 20 can then rotate relative to the main unit 10 to the covered position in a plane parallel to the side of the main unit 10 where the receiving groove 11 is located, under the power provided by the rotating connection assembly 30. During the rotation of the closed body 20, the user only needs to operate the stop release component 40, without needing to operate the closed body 20 itself. The closed body 20 remains open under the action of the rotating connecting component 30. Thus, the heated non-combustible product used in the heating chamber 510, when inverted, naturally falls out. Since the user's hands do not need to touch the closed body 20, the risk of burns from the falling heated non-combustible product is greatly reduced, improving the safety of this heated non-combustible device.

[0054] See Figure 4 and Figure 5As shown, the rotary connection assembly 30 includes a rotary shaft 31 and a rotary drive 32. The rotary shaft 31 is disposed on the main unit 10 in a direction parallel to the axis of the heating chamber 510. Specifically, a portion of the shaft of the rotary shaft 31 is fixed to the main unit 10. The enclosure 20 is rotatably connected to the main unit 10 via the rotary shaft 31, and the enclosure 20 can rotate relative to the main unit 10 around the axis of the rotary shaft 31. The rotary drive 32 is installed between the enclosure 20 and the main unit 10. The rotary drive 32 is used to drive the enclosure 20 to rotate relative to the main unit 10 to the open position when the stop release assembly 40 is in the released state. Preferably, the axis of the heating chamber 510 is coaxial with the axis of the main unit 10, so that when the enclosure 20 rotates relative to the main unit 10, the enclosure 20 can rotate in a plane parallel to the side of the main unit 10 where the receiving groove 11 is provided.

[0055] The rotary drive 32 can be electrically driven, which can automatically rotate the enclosure 20 relative to the host to the open or closed position. Of course, the rotary drive 32 can also be mechanical, which can automate the rotation to the open position, while the rotation from the open position to the closed position can be achieved by manual pushing.

[0056] In this application, to reduce costs, the rotary drive component 32 includes a torsion spring 321, which is sleeved on the rotary shaft 31, such as... Figure 8 As shown, the enclosed body 20 is provided with a first slot 22, such as Figure 5 As shown, the main unit 10 is provided with a second slot 13. The first free end 3211 of the torsion spring 321 is engaged with the first slot 22 of the closure 20, and the second free end 3212 of the torsion spring 321 is engaged with the second slot 13 of the main unit 10. During the process of the closure 20 rotating from the open position to the covered position relative to the main unit 10 in a plane parallel to the side where the receiving groove 11 is provided, around the axis of rotation 31, the torsion spring 321 is elastically compressed and stores elastic potential energy. When the stop release assembly 40 releases the stop part 21, the torsion spring 321 releases its elastic potential energy, forcing the closure 20 to rotate from the covered position to the open position relative to the main unit 10 in a plane parallel to the side where the receiving groove 11 is provided, around the axis of rotation 31, thus providing power for the rotation of the closure 20.

[0057] During the process of the enclosed body 20 rotating from the covered position to the open position relative to the main unit 10 in a plane parallel to the side where the receiving groove 11 is provided on the main unit 10, in order to keep it in the open position, see Figure 5 and Figure 8As shown, the side of the enclosure 20 facing the host 10 is provided with a limiting member 23, and the side of the host 10 with the receiving groove 11 is also provided with a limiting fitting part 14. The limiting member 23 and the limiting fitting part 14 cooperate with each other to limit the angle of rotation of the enclosure 20 relative to the host 10 when the enclosure 20 rotates relative to the host 10 in a plane parallel to the side of the host 10 with the receiving groove 11, so as to limit the enclosure 20 to the open position that can expose the heating cavity 510.

[0058] It should be noted that the limiting fitting part 14 is the side wall of the internal cavity of the host 10. Of course, in some embodiments, since the limiting member 23 protrudes from the closed body 20, the host 10 can adopt a hollow structure with an opening on one side of the receiving groove 11. Of course, the receiving groove 11 can be formed on other block structures and fixed in the cavity of the host 10.

[0059] In one embodiment of this application, the torsion spring 321 instantaneously releases its elastic potential energy, causing the closed body 20 to rotate rapidly. To address this, the rotary connection assembly 30 provided in this application also includes a damping element, see [link to relevant documentation]. Figure 4 , Figure 5 , Figure 8 As shown, the enclosed body 20 has a first shaft hole 24. A portion of the rotating shaft 31 is fixedly connected to the side of the main unit 10 with a receiving groove 11, and the remaining portion of the rotating shaft 31 passes through the first shaft hole 24. In a specific embodiment, the main unit 10 has a screw hole 15, and the portion of the rotating shaft 31 fixed to the main unit 10 has external threads and is fixedly connected to the main unit 10 by screwing into the screw hole 15. A damping element is disposed between the rotating shaft 31 and the first shaft hole 24 to reduce the rotational speed of the enclosed body 20 relative to the main unit 10.

[0060] In this application, a protrusion 33 is also provided in the radial direction of the rotating shaft 31. The protrusion 33 is located on the part of the rotating shaft 31 that is placed outside the enclosure 20, which can prevent the enclosure 20 from detaching from the rotating shaft 31.

[0061] See Figures 1-7 as well as Figure 10 As shown, the enclosed body 20 is also provided with a suction nozzle 60, which has a through suction nozzle channel 610. The suction nozzle channel 601 is connected to the aerosol outflow channel 610, such as... Figure 10As shown, the side wall of the suction nozzle 60 has an air inlet 611 that communicates with the suction nozzle channel 601, and the inner wall of the side wall of the suction nozzle 60 has a first air inlet channel 612. The heating assembly 50 includes a heating cup 51, and the side wall of the heating cup 51 has a second air inlet channel 511. The inner cavity of the heating cup 51 is formed as a heating chamber 510. When the sealing body 20 covers the heating chamber 510, the first air inlet channel 512 communicates with the second air inlet channel 511. The end of the second air inlet channel 511 away from the first air inlet channel 512 has an air delivery hole 512 located on the inner wall of the heating cup 51. The air inlet 611, the first air inlet channel 512, the second air inlet channel 511, the air delivery hole 512, and the heating chamber 510 are interconnected. In actual use, the user draws air through the nozzle 60, while external air enters the heating chamber 510 through the air inlet 611, the first air inlet channel 512, the second air inlet channel 511, and the air delivery hole 512.

[0062] See Figure 10 As shown, the heating assembly 50 also includes a heat exchange core 52, a heating chamber 53, and a gas collecting plate 54. The heat exchange core 52, the gas collecting plate 54, and the heating chamber 53 are sequentially fixed inside the heating cup 51 along the height direction of the heating cup 51. The heat exchange core 52 is located between the heating chamber 53 and the bottom of the heating cup 51. The heat exchange core 52 is used to heat the gas flowing into the heating cup 51 from the gas inlet 512. The heating chamber 53 defines a heating cavity 510.

[0063] Specifically, the heat exchange core 52 is provided with multiple heat exchange holes 521 through it, and the air collecting plate 54 is provided with multiple air collecting holes 541 through it. External air enters into each heat exchange hole 521 of the heat exchange core 52 through the air supply hole 512. The heat exchange core 52 can generate heat to heat the air flowing through the heat exchange holes 521. The heated airflow is then transported to the heating chamber 510 defined by the heating chamber 53 through the air collecting holes 541.

[0064] In some embodiments, an air-gathering block 513 is also provided at the air inlet 512, which can increase the flow rate of external air entering through the air inlet 512.

[0065] See also Figure 10As shown, a reducing pipe 62 is also provided in the inner cavity of the suction nozzle 60, and an extension 63 is defined at the top end of the suction nozzle 60. The reducing pipe 62 sequentially forms a first mixing chamber 621, an acceleration chamber 622, and a second mixing chamber 623 along the axial direction of the suction nozzle 60. The first mixing chamber 621, the acceleration chamber 622, and the second mixing chamber 623 are sequentially arranged along the airflow outlet direction and are interconnected, so the aerosol is output sequentially through the first mixing chamber 621, the acceleration chamber 622, and the second mixing chamber 623. In this embodiment, a first one-way valve 55 is also provided on the sealed body 20, and a second one-way valve 56 is also provided between the air outlet 512 and the second air inlet channel 511. The first one-way valve 55 is located on the channel wall of the second air inlet channel 511 and communicates with the first mixing chamber 621, allowing a small portion of the air entering through the second air inlet channel 511 to enter the first mixing chamber 621 to cool the aerosol. The second one-way valve 56 allows air entering through the second air intake channel 511 to flow unidirectionally through the air supply port 512 and supply it to the heat exchange port 521, preventing aerosol leakage. The acceleration chamber 622 is preferably a pipe with a radial dimension at least smaller than that of the first mixing chamber 621, which can accelerate the output flow rate of the aerosol and reduce suction resistance. The second mixing chamber 623 can buffer the aerosol accelerated by the acceleration chamber 622, enabling it to achieve further cooling.

[0066] See Figures 6-8 As shown, the stop-release assembly 40 includes a blocking member 41, which can be in a stopped state and a released state. The blocking member 41 is connected to the main unit 10, and the stop part 21 is a slot 211 provided in the closed body 20. When the closed body 20 is in the stopped state, and at this time the closed body 20 is in the state of covering the heating chamber 510, the blocking member 41 is engaged with the slot 211 to limit the closed body 20 and keep it in the covered position. When the closed body 20 is in the released state, the blocking member 41 moves away from the closed body 20 and disengages from the slot 211, thus releasing the closed body 20. The torsion spring 321 releases its elastic potential energy, causing the closed body 20 to rotate from the covered position to the open position.

[0067] To enable operation of the blocking member 41, in this embodiment, the stop release assembly 40 further includes a release member 42. The main unit 10 has a through hole 12, and the release member 42 is slidably inserted into the through hole 12 between the stop position and the release position. The blocking member 41 is connected to the release member 42. By operating the release member 42, the release member 42 causes the blocking member 41 to engage with the slot 211, thus placing the release member 42 in the stop position. By operating the release member 42, the release member 42 causes the blocking member 41 to disengage from the slot 211, thus placing the release member 42 in the release position.

[0068] In a specific embodiment, the release member 42 is reciprocally slidably inserted into the through hole 12, and can be in a stop position or a release position relative to the through hole 12. A limiting protrusion 421 is also provided on the release member 42. The limiting protrusion 421 is located on the part of the release member 42 placed inside the host 10. The limiting protrusion 421 cooperates with the inner wall of the host 10 to restrict the release member 42 from disengaging from the through hole 12.

[0069] To facilitate operation of the release member 42, the part of the release member 42 located outside the main unit 10 is also provided with a pressing part 422. The pressing part 422 can be pressed, and the pressing force is applied to the blocking member 41 through the release member 42, so that the release member 42 drives the blocking member 41 to slide from the stop position to the release position.

[0070] When the release member 42 moves the blocking member 41 to the unlocked position, after the force applied to the pressing part 422 is removed, in order to facilitate the automatic switching of the blocking member 41 to the stop position, the stop release assembly 40 provided in this embodiment also includes an elastic reset member 43. The main unit 10 is provided with a limiting member 16 inside, and the elastic reset member 43 is disposed between the limiting member 16 and the blocking member 41. The elastic reset member 43 is used to apply an elastic force away from the limiting member 16 to the blocking member 41 so as to keep the blocking member 41 engaged in the slot when the release member 42 is in the stop position. When the blocking member 41 switches from the stop position to the release position under the action of the release member 42, the elastic reset member 43 is elastically compressed and stores elastic potential energy. That is, after the force applied to the pressing part 422 is removed, the elastic reset member 43 releases the elastic potential energy and switches the blocking member 41 from the release position to the stop position.

[0071] See Figure 9 As shown, the blocking member 41 includes a blocking portion 411, a first connecting portion 412, and a second connecting portion 413. The first connecting portion 412 is disposed between the blocking portion 411 and the second connecting portion 413, and the second connecting portion 413 abuts against the releasing member 42, as shown. Figure 7 As shown, the host 10 is also provided with a rotating shaft 17 inside. The rotating shaft 17 is rotatably connected to the connection between the first connecting part 412 and the blocking part 411. In some embodiments, a second shaft hole 414 is also provided at the connection between the first connecting part 412 and the blocking part 411. The rotating shaft 17 is rotatably inserted into the second shaft hole 414, so that the blocking part 41 is rotatably connected to the inside of the host 10.

[0072] like Figure 9As shown, there is a first included angle between the blocking part 411 and the first connecting part 412, and a second included angle between the first connecting part 412 and the second connecting part 413. Specifically, the second connecting part 413 is arranged vertically, the first connecting part 412 is inclined to connect the second connecting part 413 in a direction away from the limiting member 16, and the blocking part 411 is inclined to connect the first connecting part 412 in a direction close to the limiting member 16. The first connecting part 412 and the blocking part 411 form an approximately V-shaped structure. When the blocking member 41 rotates around the pivot 17 in a first rotation direction or a second rotation direction, the blocking part 411 is engaged with or disengaged from the slot 211.

[0073] In a specific embodiment, when the blocking part 411 engages with the slot 211, a pressing force is applied to the pressing part 422. The releasing member 42 moves, causing the blocking member 41 to rotate around the pivot 17 in the second rotation direction, thus disengaging the blocking part 411 from the slot 211. During this process, the elastic reset member 43 stores elastic potential energy. When the force applied to the pressing part 422 is removed, the elastic reset member 43 releases the elastic potential energy, allowing the blocking member 41 to rotate around the pivot 17 in the first rotation direction, so that the blocking part 411 engages with the slot 211.

[0074] In summary, in the heated non-combustible device provided in this application, by operating the stop release component, the stop release component releases the stop part, and the closure body can rotate relative to the main unit in a plane parallel to the receiving groove on the side of the main unit under the power provided by the rotating connecting component, to the covered position. During the rotation of the closure body, the user only needs to operate the stop release component, without needing to operate the closure body itself. The closure body is in an open state under the action of the rotating connecting component. Thus, when the heated non-combustible product is used up in the heating chamber in an inverted manner, it falls naturally. Since the user's hands do not need to touch the closure body, the risk of burns from the falling heated non-combustible product is greatly reduced. This improves the safety of using this heated non-combustible device.

[0075] The above examples illustrate this application only to aid understanding and are not intended to limit its scope. Those skilled in the art to which this application pertains can make various simple deductions, modifications, or substitutions based on the ideas presented.

Claims

1. A heating non-combustible device, characterized in that, include: The host computer has a receiving slot on one side; A heating assembly is disposed in the receiving groove, the heating assembly having a heating chamber for accommodating a heated non-combustible product; A closed body, wherein the closed body is provided with an aerosol outflow channel; A rotating connection assembly is disposed between the enclosure and the main unit. The enclosure can rotate relative to the main unit in a plane parallel to the side of the main unit where the receiving groove is provided, to an open position or a covered position. In the covered position, the enclosure covers the heating cavity. In the open position, the closed body opens the heating cavity; A stop release assembly is disposed on the host unit. The closure body has a stop portion. The stop release assembly has a stop state and a release state. In the stop state, the stop release assembly stops at the stop portion to restrict the closure body from being in the covered position relative to the host unit. In the release state, the stop release assembly releases the stop portion to allow the closure body to rotate relative to the host unit to the open position via the rotary connection assembly.

2. The heating non-combustible device as described in claim 1, characterized in that, The rotary connection assembly includes a rotary shaft and a rotary drive. The rotary shaft is disposed on the host in a direction parallel to the axis of the heating chamber. The enclosure is rotatably connected to the host via the rotary shaft, and the enclosure can rotate relative to the host about the axis of the rotary shaft. The rotary drive is installed between the enclosure and the host, and the rotary drive is used to drive the enclosure to rotate relative to the host to the open position when the stop release assembly is in the released state.

3. The heating non-combustible device as described in claim 2, characterized in that, The rotary drive component includes a torsion spring, which is sleeved on the rotary shaft. The enclosed body has a first slot, and the main unit has a second slot. The first free end of the torsion spring is engaged with the first slot of the enclosed body, and the second free end of the torsion spring is engaged with the second slot of the main unit.

4. The heating non-combustible device as described in claim 2, characterized in that, The enclosure is provided with a limiting member on the side facing the host, and the host is provided with a limiting fitting part on the side where the receiving groove is located. The limiting member and the limiting fitting part cooperate with each other to limit the angle of rotation of the enclosure relative to the host when the enclosure rotates relative to the host in a plane parallel to the side of the host where the receiving groove is located.

5. The heating non-combustible device as described in claim 1, characterized in that, The enclosure is also provided with a suction nozzle, which has a through-hole that is connected to the aerosol outflow channel. The side wall of the suction nozzle is provided with an air inlet that is connected to the suction channel.

6. The heating non-combustible device as described in any one of claims 1-5, characterized in that, The stop-release assembly includes a blocking member, which can be in a stop state and a release state. The blocking member is connected to the host, and the stop portion is a slot provided in the enclosure. In the stop state, the blocking member is engaged with the slot. In the release state, the blocking member moves away from the enclosure and disengages from the slot.

7. The heating non-combustible device as described in claim 6, characterized in that, The stop release assembly further includes a release member. The main unit has a through hole, and the release member can slide back and forth between the stop position and the release position in the through hole. The blocking member is connected to the release member. In the stop position, the release member drives the blocking member to engage with the slot. In the release position, the release member drives the blocking member to disengage from the slot.

8. The heating non-combustible device as described in claim 7, characterized in that, The stop release assembly further includes an elastic reset member. The host is internally provided with a limiting member. The elastic reset member is disposed between the limiting member and the blocking member. The elastic reset member is used to apply an elastic force away from the limiting member to the blocking member so as to keep the blocking member engaged in the slot when the release member is in the stop position.

9. The heating non-combustible device as described in claim 8, characterized in that, The release member also has a protruding portion, which is located in the part of the release member placed inside the host. The protruding portion cooperates with the inner wall of the host to prevent the release member from disengaging from the through hole. The part of the release member placed outside the host also has a pressing portion, which is pressed to cause the release member to drive the blocking member to slide from the stop position to the release position.

10. The heating non-combustible device as described in claim 9, characterized in that, The blocking member includes a blocking part, a first connecting part, and a second connecting part. The first connecting part is disposed between the blocking part and the second connecting part, and the second connecting part abuts against the releasing member. The host has a rotating shaft inside, and the connection between the first connecting part and the blocking part is rotatably connected to the rotating shaft. The blocking part and the first connecting part have a first included angle, and the first connecting part and the second connecting part have a second included angle. The blocking member rotates around the rotating shaft in a first rotation direction or a second rotation direction, so that the blocking part is engaged with or disengaged from the slot.