CN114515020A - Cooling assembly and preparation method thereof, and heating non-combustion smoke cartridge and preparation method thereof - Google Patents

Abstract

The application provides a preparation method of a cooling assembly, a preparation method of a heating non-combustion cartridge, the cooling assembly and the heating non-combustion cartridge. The preparation method of the cooling assembly comprises the following steps: providing a plurality of cooling pipes, wherein each cooling pipe comprises a first end and a second end which are arranged oppositely, and each cooling pipe is provided with an accommodating space; placing the first ends into the accommodating space in the glue storage piece, and contacting the first ends with the binder in the accommodating space so that the end surfaces of the first ends of the plurality of cooling pipes are flush and adhered with the binder; providing a first breathable sealing piece, and attaching the end face of the first end adhered with the adhesive to the first breathable sealing piece; cutting the first ventilation sealing element to form a first ventilation sealing part for sealing the end surface of the first end; and filling the cooling part into the accommodating space of the cooling pipe from the second end. The preparation method of the cooling assembly improves the sealing process efficiency of the cooling pipe, and therefore the filling efficiency of the cooling portion is improved.

Description

Cooling assembly and preparation method thereof, and heat-not-burn cartridge and preparation method thereof

technical field

The application relates to the field of electronic cigarettes, and in particular to a method for preparing a cooling component, a method for preparing a heat-not-burn cartridge, a cooling component and a heat-not-burn cartridge.

Background technique

With the development of science and technology, more and more users are using HNB pods. The aerosol matrix in HNB pods will be heated to form high-temperature aerosols. Therefore, HNB pods need to be equipped with a cooling unit. cooling components for cooling. During the processing of the cooling assembly, when the cooling part is filled into the cooling pipe, one end of the cooling pipe needs to be sealed first. However, the sealing of the cooling assembly is difficult due to the difficulty in the connection between the seal and the cooling pipe, resulting in a low efficiency of the sealing preparation process of the cooling assembly. , thereby reducing the filling efficiency of the cooling section.

SUMMARY OF THE INVENTION

In a first aspect, the present application provides a method for preparing a cooling assembly, the method for preparing a cooling assembly includes providing a plurality of cooling pipes, the cooling pipes include a first end and a second end arranged opposite to each other, and the cooling The tube has an accommodating space, and the first end is put into the accommodating space in the glue accumulating member, and is in contact with the binder in the accommodating space, so that the first ends of the plurality of cooling pipes are The end face of the end is flush and the adhesive is adhered, a first breathable seal is provided, and the end face of the first end adhered with the adhesive is attached to the first breathable seal, and the first breathable seal is attached. A ventilating seal is cut to form a first ventilating seal portion sealing the first end, and the cooling portion is filled into the accommodating space of the cooling pipe from the second end.

Wherein, after "filling the cooling part from the second end into the accommodating space of the cooling pipe", the preparation method of the cooling assembly further includes: turning the glue accumulating member over, placing the second end in the accommodating space of the cooling pipe. into the accommodating space in the gel storage member, and contact with the adhesive in the accommodating space, so that the end faces of the second ends of the plurality of cooling pipes are flush and adhered with adhesive agent, providing a second breathable seal, attaching the end face of the second end with the adhesive to the second breathable seal, and cutting the second breathable seal to seal the The second gas permeable seal portion of the end face of the second end.

Wherein, after the "provide a plurality of cooling pipes, the cooling pipes include a first end and a second end arranged opposite to each other, and the cooling pipes have a receiving space", after the "put the first end on the into the accommodating space in the gel storage member, and contact with the adhesive in the accommodating space, so that the end faces of the first ends of the plurality of cooling pipes are flush and adhered with the adhesive ” before, the preparation method of the cooling assembly further includes scraping off the adhesive in the glue storage member that exceeds a first preset height, and the range of the first preset height h1 is: 0.1mm≤h1≤0.3 mm.

Wherein, the "putting the first end into the accommodating space in the glue accumulating member and contacting the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes is The end face of the end is flush and the adhesive is adhered to it" includes arranging the glue accumulating member on one side of the first end, and is spaced from the first end, from the second end to the The first end pushes the cooling tube, and the pushing force F is: 1N≤F≤1.5N, and the end face of the first end is immersed in the adhesive in the accommodating space until the first end The end face of the end abuts the glue accumulating member, so that the portion of the first end adjacent to the end face of the first end is adhered with adhesive.

Wherein, after the "providing a first air-permeable seal, and attaching the end face of the first end to which the adhesive is adhered with the first air-permeable seal", in the "applying the first air-permeable seal" Before the ventilating seal is cut to form a first ventilating sealing portion that seals the first end, the preparation method of the cooling assembly further includes attaching the first ventilating seal to the end face of the first end. The partially surrounded area is cut to form first ventilation holes.

Wherein, the “cutting the area surrounded by the part of the first air-permeable seal and the end face of the first end to form a first air hole” includes selecting the first air-permeable seal and the A predetermined area in the area surrounded by the end face-fitted part of the first end, and the outer contour of the predetermined area is cut to form a first ventilation hole.

Wherein, the “cutting the area surrounded by the part of the first air-permeable seal and the end face of the first end to form a first air hole” includes selecting the first air-permeable seal and the A predetermined area in the area surrounded by the end face-fitted part of the first end, and the first ventilation hole is formed by cutting the inside of the predetermined area.

In a second aspect, the present application also provides a method for preparing a heat-not-burn pod, the method for preparing a heat-not-burn pod includes providing a tube body, the tube body has a accommodating space, and a sealing member is used to seal the tube One end of the body, the smoking member is loaded into the accommodating space from the end away from the sealing member, and the smoking member is adjacent to the sealing member, and the method for preparing a cooling assembly according to the second aspect is prepared. The cooling assembly is installed into the accommodating space from one end away from the sealing member, and the first end is arranged adjacent to the smoking member relative to the second end, and the filter member is installed from the end away from the sealing member. into the accommodating space.

In a third aspect, the present application also provides a cooling assembly, the cooling assembly includes a cooling pipe, the cooling pipe includes a first end and a second end arranged opposite to each other, the cooling pipe has a receiving space, and a cooling part , the cooling part is accommodated in the accommodating space, and the volume ratio a of the cooling part to the accommodating space is: 20%≦a≦60%, and the cooling component further includes a first adhesive layer and a first The air-permeable sealing part, and/or, the cooling assembly further includes a second adhesive layer and a second air-permeable sealing part, when the cooling assembly includes a first adhesive layer and a first air-permeable sealing part: the first adhesive layer and the first air-permeable sealing part: The junction layer is arranged on the end face of the first end and is located at a portion of the first end adjacent to the end face of the first end, and the first air-permeable sealing part is bonded to the first end through the first adhesive layer. The end face of one end, when the cooling component includes a second adhesive layer and a second air-permeable sealing part: the second adhesive layer is arranged on the end face of the second end and is located at the second end adjacent to the first As part of the end surfaces of the two ends, the second air-permeable sealing portion is bonded to the end surfaces of the second end through the second adhesive layer.

In a fourth aspect, the present application also provides a heat-not-burn pod, the heat-not-burn pod includes a tube body, the tube body has a accommodating space, and a sealing member, the sealing member is sealed to the first tube One end of the body, a smoking member, the smoking member is arranged in the accommodating space and is arranged adjacent to the sealing member, and the cooling assembly according to the third aspect, the cooling assembly is arranged in the accommodating space, is located at one end of the smoking member away from the sealing member, and the first air-permeable sealing portion is adjacent to the smoking member compared to the cooling portion, and a filter member, the filter member is disposed in the accommodating space, and is arranged on the side of the cooling assembly away from the smoking member.

The present application provides a method for preparing a cooling assembly. First, the end face of the first end of the cooling pipe to which the adhesive is adhered is attached to the first air-permeable seal, and then the first air-permeable seal is applied. The first air-permeable sealing part is formed to seal the end face of the first end, and then the cooling part is filled into the receiving space of the cooling pipe from the second end. Therefore, when sealing the end face of the first end of the cooling pipe in the preparation method of the cooling assembly provided in the present application, it is not necessary to align the first air-permeable sealing part and the end face of the first end one by one, and the sealing can be performed quickly. The end face of the first end is filled with the cooling part. Therefore, the preparation method of the cooling assembly provided by the present application improves the sealing process efficiency of the cooling pipe, thereby improving the filling efficiency of the cooling part.

Description of drawings

In order to explain the technical solutions of the embodiments of the present application more clearly, the following briefly introduces the accompanying drawings that need to be used in the implementation manner. As far as technical personnel are concerned, other drawings can also be obtained based on these drawings without any creative effort.

FIG. 1 is a schematic flowchart of a method for preparing a cooling assembly provided by an embodiment of the present application.

FIG. 2 is a schematic structural diagram of a cooling assembly prepared by the method for preparing a cooling assembly provided in the embodiment of FIG. 1 .

FIG. 3 is an exploded perspective view of the cooling assembly provided in the embodiment of FIG. 2 .

FIG. 4 is a schematic structural diagram of a cooling pipe in the cooling assembly provided in the embodiment of FIG. 2 .

FIG. 5 is a schematic flowchart of a method for preparing a cooling assembly according to another embodiment of the present application.

FIG. 6 is a schematic structural diagram of a cooling assembly prepared by the method for preparing a cooling assembly provided in the embodiment of FIG. 5 .

FIG. 7 is an exploded perspective view of the cooling assembly provided in the embodiment of FIG. 6 .

FIG. 8 is a schematic flowchart of a method for preparing a cooling assembly provided by another embodiment of the present application.

FIG. 9 is a schematic flowchart of a method for preparing a cooling assembly according to another embodiment of the present application.

FIG. 10 is a schematic flowchart of a method for preparing a first end with an adhesive in the method for preparing a cooling assembly provided by the embodiment of FIG. 1 .

FIG. 11 is a schematic flowchart of a method for preparing a second end with an adhesive in the method for preparing a cooling assembly provided by the embodiment of FIG. 5 .

FIG. 12 is a schematic flowchart of a method for preparing a cooling assembly according to another embodiment of the present application.

FIG. 13 is a schematic structural diagram of the first air-permeable sealing portion prepared by the method for preparing the cooling assembly provided in the embodiment of FIG. 12 .

FIG. 14 is a schematic flowchart of a method for preparing a first ventilation hole provided in an embodiment of the method for preparing a cooling component provided in the embodiment of FIG. 12 .

FIG. 15 is a schematic flowchart of a method for preparing a first ventilation hole provided by another embodiment in the method for preparing a cooling component provided in the embodiment of FIG. 12 .

FIG. 16 is a schematic flowchart of a method for preparing a cooling assembly according to another embodiment of the present application.

FIG. 17 is a schematic structural diagram of the second air-permeable sealing portion prepared by the method for preparing the cooling assembly provided in the embodiment of FIG. 16 .

FIG. 18 is a schematic flowchart of a method for preparing a second ventilation hole provided in an embodiment in the method for preparing a cooling component provided in the embodiment of FIG. 16 .

FIG. 19 is a schematic flowchart of a method for preparing a second ventilation hole provided by another embodiment in the method for preparing a cooling component provided in the embodiment of FIG. 16 .

FIG. 20 is a schematic flowchart of a method for preparing a heat-not-burn pod according to an embodiment of the present application.

FIG. 21 is a schematic structural diagram of a heat not burn cartridge prepared by the method for preparing a heat not burn cartridge provided by the embodiment of FIG. 20 .

FIG. 22 is a schematic structural diagram of a cooling assembly provided by an embodiment of the present application.

FIG. 23 is an enlarged schematic view of part I in the cooling assembly provided by the embodiment of FIG. 22 .

FIG. 24 is an enlarged schematic view of II in the cooling assembly provided by the embodiment of FIG. 22 .

FIG. 25 is a schematic structural diagram of a heat not burn cartridge provided by an embodiment of the application.

FIG. 26 is an exploded perspective view of the heat-not-burn pod provided by the embodiment of FIG. 25 .

Reference numerals: heat not burn cartridge 1; cooling assembly 10; tube body 20; sealing member 30; smoking member 40; filter member 50; The sealing portion 14; the first adhesive layer 15; the second adhesive layer 16; the receiving space 21; the first end 111; the second end 112; the receiving space 113;

Detailed ways

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. Obviously, the described embodiments are only a part of the embodiments of the present application, but not all of the embodiments. Based on the embodiments in the present application, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the protection scope of the present application.

The terms "first", "second" and the like in the description and claims of the present application and the above drawings are used to distinguish different objects, rather than to describe a specific order. Furthermore, the terms "comprising" and "having" and any variations thereof are intended to cover non-exclusive inclusion. For example, a process, method, system, product or device comprising a series of steps or units is not limited to the listed steps or units, but optionally also includes unlisted steps or units, or optionally also includes For other steps or units inherent to these processes, methods, products or devices.

Reference herein to "an example" or "an implementation" means that a particular feature, structure, or characteristic described in connection with an example or implementation can be included in at least one example of the present application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor a separate or alternative embodiment that is mutually exclusive of other embodiments. It is explicitly and implicitly understood by those skilled in the art that the embodiments described herein may be combined with other embodiments.

An embodiment of the present application provides a method for preparing a cooling component. Please refer to FIGS. 1 , 2 , 3 and 4 together. FIG. 1 is a schematic flowchart of a method for preparing a cooling component according to an embodiment of the present application; FIG. 2 is a schematic diagram of the method for preparing a cooling component according to the embodiment of FIG. Schematic diagram of the structure of the prepared cooling assembly; FIG. 3 is an exploded perspective view of the cooling assembly provided by the embodiment of FIG. 2 ; FIG. 4 is a schematic structural diagram of the cooling pipe in the cooling assembly 10 provided by the embodiment of FIG. 2 . In this embodiment, the method for preparing the cooling assembly 10 includes providing a plurality of cooling pipes 11 . The cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space. 113. The first ends 111 are put into the accommodating space in the glue accumulator, and contact with the adhesive in the accommodating space, so that the first ends 111 of the plurality of cooling pipes 11 are The end faces are flush and adhered with adhesive. A first breathable seal is provided, and the end face of the first end 111 to which the adhesive is adhered is attached to the first breathable seal. The first air-permeable sealing member is cut to form the first air-permeable sealing portion 12 that seals the first end 111 . and filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the second end 112 .

In this embodiment, the cooling assembly 10 is mainly applied to the HNB pod 1 . The heat-not-burn pod 1 will form a high-temperature aerosol after being heated, and the temperature is 200-380° C. The cooling component 10 is used to cool the high-temperature aerosol to a temperature suitable for suction.

In this embodiment, the preparation method of the cooling assembly 10 includes but is not limited to S11, S12, S13, S14 and S15. Next, S11, S12, S13, S14 and S15 will be described in detail.

S11 , the preparation method of the cooling assembly 10 includes providing a plurality of cooling pipes 11 , the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113 .

Wherein, in this embodiment (please refer to FIG. 4 ), the cooling pipe 11 is a channel for circulating aerosol, the high temperature aerosol flows through the cooling pipe 11 , and after the cooling of the cooling pipe 11 , the air The temperature of the sol will decrease somewhat. The cooling pipe 11 is a food-grade material, which can reduce or even not produce toxic substances when heated. For example, the material of the cooling pipe 11 may be, but not limited to, food-grade materials such as white cardboard or kraft paper. Specifically, the cooling pipe 11 can be, but not limited to, white cardboard of 50-200 g/m2, kraft paper of 50-200 g/m2, and the like. In order to maintain the concentration of aerosol and the sense of resistance of pumping aerosol, the range of the diameter D1 of the cooling pipe 11 is: 6mm≦D1≦6.6mm. If the diameter D1 of the cooling tube 11 is too small, the resistance to suction aerosol will be too large, and if the diameter D1 of the cooling tube 11 is too large, the concentration of aerosol in the cooling tube 11 will be too high Small, affecting the taste of the aerosol inhaled. Therefore, the range of the diameter D1 of the cooling pipe 11 is: 6 mm≦D1≦6.6 mm, which can make the aerosol concentration in the cooling pipe 11 full while ensuring a small suction resistance. It should be noted that the suction resistance refers to the resistance encountered by sucking the aerosol into the cooling tube 11 and sucking the aerosol out of the cooling tube 11 .

S12, put the first ends 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the first ends of the plurality of cooling pipes 11 The end faces of 111 are flush and adhered with adhesive.

Among them, in this embodiment, the binder is a food-grade binder, which can reduce or even not produce poison when heated. For example, the binder can be, but is not limited to, one or more food-grade binders among glutinous rice glue, lap glue, straw glue, white latex, and the like. In this embodiment, the end faces of the first ends 111 are immersed in the adhesive in the accommodating space and abutted against the bottom of the gel storage member, so that the first ends of the plurality of cooling pipes 11 are immersed in the adhesive. The end surface of one end 111 is flush and adhered with an adhesive, so that the subsequent gluing process of the plurality of cooling tubes 11 is more stable and firm.

S13 , providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal.

Wherein, in this embodiment, the first breathable sealing member is a food-grade material, which can reduce or even not produce poison when heated. For example, the material of the first air-permeable seal may be, but not limited to, food-grade materials such as silk tissue paper, high-air-permeability paper, or tallow paper. Specifically, the first air-permeable sealing member may be, but not limited to, 10-50 g/m2 silk tissue paper, 10-50 g/m2 high air permeability paper, or 45-105 g/m2 tallow paper. It should be noted that, in this embodiment, the size of the first air-permeable seal is much larger than the size of the end face of the first end 111. Therefore, the first air-permeable seal can be used with a plurality of the air-permeable seals at one time. The end surfaces of the first ends 111 of the cooling pipes 11 are bonded together.

S14 , cutting the first air-permeable sealing member to form the first air-permeable sealing portion 12 for sealing the first end 111 .

Wherein, in this embodiment, the first air-permeable sealing member is cut along the outline of the cooling pipe 11, so that the formed first air-permeable sealing part 12 and the cooling pipe 11 have the same diameter, So that the first air-permeable sealing portion 12 can completely seal the end surface of the first end 111 without affecting the subsequent preparation and assembly of the cooling assembly 10 .

In one embodiment, a cutter is used to cut the first air-permeable sealing member along the outline of the cooling pipe 11 to form a first air-permeable sealing portion 12 that seals the end face of the first end 111 . The cutting tool is a hard metal material, for example, the material of the cutting tool can be, but not limited to, high carbon steel, alloy tool steel or black steel. Further, heat treatment, crushing and electroplating are performed on the cutter to increase the strength, hardness, toughness and wear resistance of the cutting edge of the cutter, so that the first air-permeable sealing member along the cooling pipe 11 is not affected. Outline contour cutting is more efficient and quality. Specifically, it is possible but not limited to use a precision turning machine tool for processing, the processing power P1 is: 1.5KW≤P1≤2.5KW, and the processing air pressure is 1500MPa.

In another embodiment, a laser is used to cut the first air-permeable sealing member along the outline of the cooling tube 11 to form a first air-permeable sealing portion 12 that seals the end face of the first end 111 . Specifically, the first gas-permeable seal is cut along the outline of the cooling tube 11 along the first preset path by the laser emitted by the laser head, and the translation and rotation of the laser emitted by the laser head can The first breathable seal is cut. Since the laser has high energy, the energy can be transferred to the first air-permeable seal, so that the place on the first air-permeable seal irradiated by the laser generates high temperature and burns. Also, because the diameter of the light spot irradiated by the laser light on the first air-permeable seal is in the order of micrometers and can be approximated as a point, the paths irradiated by the laser on the first air-permeable seal are connected to be approximated as lines. When the laser moves along the first preset path on the first gas-permeable seal, the laser will burn each point on the first preset path to form micron-level holes, and these burning holes are connected to form incision. Specifically, the power P2 of the device carrying the laser head is: 60W≤P2≤150W, and the power P3 of the laser head when working is: P2*60%≤P3≤P2*80%, the laser head emits The moving speed v1 of the laser is: 800mm/s≤v1≤1500mm/s, and the focal length d1 of the laser emitted by the laser head is: 30cm≤d1≤60cm. It should be noted that, in one embodiment, the laser head is fixed, and cutting is performed only by the translation and rotation of the laser light emitted by the laser head. In another embodiment, the movement of the laser emitted by the laser head is driven to perform cutting through the translation and rotation of the laser head. In this embodiment, the laser head is fixed, and only cutting is performed by the translation and rotation of the laser emitted by the laser head for exemplary illustration.

S15 , filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the second end 112 .

Wherein, please refer to FIG. 2 for the cooling assembly 10 prepared after step S15 . In this embodiment, the cooling part 13 is disposed in the receiving space 113 of the cooling pipe 11 , the cooling part 13 is a cooling material, and the cooling part 13 is used to accelerate the reduction of the temperature of the high-temperature aerosol, After the high-temperature aerosol flows through the entire cooling pipe 11 , the temperature can be quickly reduced to a suitable suction temperature (eg, 40° C.). Specifically, the cooling part 13 is a food-grade cooling material, which can reduce or even not produce toxic substances when heated. For example, the material of the cooling part 13 can include, but is not limited to, molecular sieve, medical stone, raw ore, ceramic adsorption material, far-infrared ball, filter ceramic ball, tourmaline ball, SPM copper-zinc alloy filter material and activated carbon medium at least one. In this embodiment, the cooling portion 13 can be any shape. For example, the cooling portion 13 can be, but not limited to, a particle shape, a strip shape, or a block shape, as long as the cooling portion 13 can be filled to In the cooling pipe 11, it is enough to play the role of cooling. Specifically, the range of the volume ratio of the cooling portion 13 to the accommodation space 113 is: 20%≦a≦60%, so that the cooling assembly 10 can have the cooling efficiency while maintaining the cooling efficiency of the cooling portion 13 . Appropriate suction resistance. If the volume ratio a of the cooling part 13 to the accommodation space 113 is too large, the resistance of the aerosol passing through the cooling part 13 will increase, so that the suction resistance is too large. If the volume ratio a of the cooling portion 13 to the receiving space 113 is too small, the contact area between the cooling portion 13 and the aerosol will be reduced, thereby reducing the cooling effect of the cooling portion 13 .

The present application provides a method for preparing a cooling assembly 10. First, the end face of the first end 111 of the cooling pipe 11 adhered with the adhesive is attached to the first air-permeable seal, and then A breathable sealing member is cut to form the first breathable sealing portion 12 on the end face of the first end 111 , and then the cooling portion 13 is filled from the second end 112 to the receiving space 113 of the cooling pipe 11 . middle. Therefore, when sealing the end face of the first end 111 of the cooling pipe 11 in the preparation method of the cooling assembly 10 provided in the present application, it is not necessary to align the first air-permeable sealing portion 12 and the first end 111 one by one. The end face can quickly seal the end face of the first end 111 and fill the cooling part 13 . Therefore, the method for preparing the cooling assembly 10 provided by the present application improves the sealing process efficiency of the cooling pipe 11 , thereby improving the filling efficiency of the cooling portion 13 .

Please refer to FIG. 5 , FIG. 6 and FIG. 7 together. FIG. 5 is a schematic flowchart of a method for preparing a cooling component provided by another embodiment of the present application;

FIG. 6 is a schematic structural diagram of a cooling assembly prepared by the method for preparing a cooling assembly provided in the embodiment of FIG. 5 ; FIG. 7 is an exploded perspective view of the cooling assembly provided by the embodiment of FIG. 6 . In the present embodiment, after “filling the cooling part 13 from the second end 112 into the receiving space 113 of the cooling pipe 11 ”, the preparation method of the cooling assembly 10 further includes turning over the gel storage member . Put the second ends 112 into the accommodating space in the gel storage member, and contact the adhesive in the accommodating space, so that the second ends of the plurality of cooling pipes 11 The end faces of 112 are flush and adhered with adhesive. A second breathable seal is provided, and the end face of the adhesive-adhered second end 112 is attached to the second breathable seal. and cutting the second air-permeable sealing member to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 .

Specifically, in this embodiment, the preparation methods of the cooling assembly 10 include but are not limited to S11, S12, S13, S14, S15, S26, S27, S28 and S29. Among them, S11 , S12 , S13 , S14 and S15 in this embodiment are the same as S11 , S12 , S13 , S14 and S15 in the previous embodiment. Next, S11, S12, S13, S14, S15, S26, S27, S28 and S29 will be described in detail.

S11 , the preparation method of the cooling assembly 10 includes providing a plurality of cooling pipes 11 , the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113 .

S12, put the first ends 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the first ends of the plurality of cooling pipes 11 The end faces of 111 are flush and adhered with adhesive.

S13 , providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal.

S14 , cutting the first air-permeable sealing member to form the first air-permeable sealing portion 12 for sealing the first end 111 .

S15 , filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the second end 112 .

S11 , S12 , S13 , S14 and S15 are the same as S11 , S12 , S13 , S14 and S15 in the previous embodiment, and will not be repeated here.

S26, inverting the glue accumulating member.

Wherein, in this embodiment, the rubber storage member is rotated by 180° to turn the rubber storage member from the side of the first end 111 to the side of the second end 112 .

S27, put the second end 112 into the accommodating space in the glue storage member, and contact with the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes 11 is The end surfaces of the two ends 112 are flush and adhered with adhesive.

Wherein, in this embodiment, the accommodating space of the glue storage member is provided with a binder, and the binder is a food-grade binder, which can reduce or even not produce poisons when heated. For example, the binder can be, but is not limited to, one or more food-grade binders among glutinous rice glue, lap glue, straw glue, white latex, and the like. In this embodiment, the end surfaces of the second ends 112 are immersed in the adhesive in the accommodating space and abutted against the bottom of the gel storage member, so that the first and second ends of the plurality of cooling pipes 11 are formed. The end surfaces of the two ends 112 are flush and adhered with an adhesive, so that the subsequent gluing process of the plurality of cooling pipes 11 is more stable and firm.

S28, providing a second air-permeable seal, and attaching the end face of the second end 112 to which the adhesive is adhered to the second air-permeable seal.

Wherein, in this embodiment, the second breathable seal is a food-grade material, which can reduce or even not produce poison when heated. For example, the material of the second air-permeable seal may be, but not limited to, food-grade materials such as silk tissue paper, high-air-permeability paper, or tallow paper. Specifically, the second air-permeable sealing member may be, but not limited to, 10-50 g/m2 silk tissue paper, 10-50 g/m2 high air permeability paper, or 45-105 g/m2 tallow paper. It should be noted that, in this embodiment, the size of the second breathable seal is much larger than the size of the end face of the second end 112, therefore, the second breathable seal can be used with a plurality of the The end surfaces of the second end 112 of the cooling pipe 11 are bonded together.

S29 , cutting the second air-permeable sealing member to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 .

6 and 7. In this embodiment, the second air-permeable seal is cut along the outline of the cooling pipe 11, so that the formed The diameter of the first air-permeable sealing portion 12 is the same as that of the cooling pipe 11 , so that the second air-permeable sealing portion 14 can completely seal the end surface of the second end 112 without affecting the subsequent operation of the cooling assembly 10 Preparation and assembly.

In one embodiment, a cutter is used to cut the second air-permeable sealing member along the outer contour of the cooling pipe 11 to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 . The cutting tool is a hard metal material, for example, the material of the cutting tool can be, but not limited to, high carbon steel, alloy tool steel or black steel. Further, heat treatment, crushing and electroplating are performed on the cutter to increase the strength, hardness, toughness and wear resistance of the cutting edge of the cutter, so that the second air-permeable sealing member along the cooling pipe 11 is not affected. Outline contour cutting is more efficient and quality. Specifically, it is possible but not limited to use a precision turning machine tool for processing, the processing power P4 is: 1.5KW≤P4≤2.5KW, and the processing air pressure is 1500MPa.

In another embodiment, a laser is used to cut the second air-permeable sealing member along the outer contour of the cooling tube 11 to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 . Specifically, the second air-permeable seal is cut along the contour of the cooling tube 11 along the second preset path by the laser emitted by the laser head, and the translation and rotation of the laser emitted by the laser head can The second breathable seal is cut. Since the laser has relatively high energy, the energy can be transferred to the second air-permeable sealing member, so that the place irradiated by the laser on the second air-permeable sealing member generates high temperature and burns. Also, because the diameter of the light spot irradiated by the laser on the second air-permeable seal is in the order of micrometers and can be approximated as a point, the paths irradiated by the laser on the second air-permeable seal are connected to be approximated as lines. When the laser moves along the second preset path on the second gas-permeable seal, the laser will burn each point on the second preset path to form micron-level holes, and these burning holes are connected to form incision. Specifically, the power P5 of the device carrying the laser head is: 60W≤P5≤150W, and the power P6 of the laser head when working is: P5*60%≤P6≤P5*80%, the laser head emits The moving speed v2 of the laser is: 800mm/s≤v2≤1500mm/s, and the focal length d2 of the laser emitted by the laser head is: 30cm≤d2≤60cm. It should be noted that, in one embodiment, the laser head is fixed, and cutting is performed only by the translation and rotation of the laser light emitted by the laser head. In another embodiment, the movement of the laser emitted by the laser head is driven to perform cutting through the translation and rotation of the laser head. In this embodiment, the laser head is fixed, and only cutting is performed by the translation and rotation of the laser emitted by the laser head for exemplary illustration.

In a method for preparing a cooling assembly 10 provided in this embodiment, the end face of the second end 112 of the cooling pipe 11 adhered with the adhesive is firstly attached to the second air-permeable seal, and then the The second air-permeable sealing member is cut along the outer contour of the cooling pipe 11 to form the second air-permeable sealing portion 14 on the end face of the second end 112 . Therefore, when sealing the end face of the second end 112 of the cooling pipe 11 in the preparation method of the cooling assembly 10 provided in the present application, it is not necessary to align the second air-permeable sealing portion 14 and the second end 112 one by one. For the end faces, the end faces of the second ends 112 of the plurality of cooling tubes 11 can be sealed at one time, and then the second breathable seals are cut to form a second breathable seal that seals the end faces of the second ends 112 part 14 to form the cooling assembly 10 . Therefore, the method for preparing the cooling assembly 10 provided in this embodiment improves the sealing process efficiency of the cooling pipe 11 , thereby improving the production efficiency of the cooling assembly 10 .

Please refer to FIG. 8 , which is a schematic flowchart of a method for preparing a cooling component according to another embodiment of the present application. In this embodiment, after the “provide a plurality of cooling pipes 11, the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113”, the Said "Put the first end 111 into the accommodating space in the glue storage member, and contact with the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes 11 is Before the end surface of the end 111 is flush and adhered with the adhesive, the preparation method of the cooling assembly 10 further includes scraping off the adhesive exceeding the first preset height in the glue accumulating member. The range of the preset height h1 is: 0.1mm≤h1≤0.3mm. It should be noted that this embodiment may be combined with any one of FIG. 1 or FIG. 5 for illustration. In this embodiment, the embodiment is combined with the embodiment in FIG. 5 for illustration, and FIG. 8 should not be construed as a reference to the present application Provided is the definition of the manufacturing method of the cooling assembly 10 .

Specifically, in this embodiment, the preparation methods of the cooling assembly 10 include but are not limited to S11, S31, S12, S13, S14, S15, S26, S27, S28 and S29. Among them, S11, S12, S13, S14, S15, S26, S27, S28 and S29 in this embodiment are the same as S11, S12, S13, S14, S15, S26, S27, S28 and S29 in the previous embodiment. Next, S11, S31, S12, S13, S14, S15, S26, S27, S28 and S29 will be described in detail.

S11 , the preparation method of the cooling assembly 10 includes providing a plurality of cooling pipes 11 , the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113 .

S31 , scraping off the adhesive in the glue storage member that exceeds a first preset height, where the range of the first preset height h1 is: 0.1mm≤h1≤0.3mm.

Wherein, in this embodiment, by scraping off the adhesive that exceeds the first preset height in the glue storage member, the height of the binder in the accommodating space of the glue storage member is kept the same, thereby After the end surface of the first end 111 is immersed in the accommodating space and abuts the bottom of the gel storage member, the first ends 111 of the plurality of cooling pipes 11 can adhere to the same height of bonding agent. Therefore, the subsequent sticking process of the cooling tubes 11 can maintain the same quality, which improves the production quality of the cooling tubes 11 . In addition, the range of the first preset height h1 is: 0.1mm≤h1≤0.3mm, which can ensure that the end face of the first end 111 can firmly fit the first air-permeable seal without affecting the first breathable seal. A breathable seal is cut to form the first breathable seal portion 12 . If the first preset height h1 is too small, that is, too little adhesive adheres to the portion of the end surface of the first end 111 adjacent to the first end 111 , the first end 111 will The end face cannot be firmly fitted to the first breathable seal. If the first preset height h1 is too large, that is, too much adhesive adheres to the portion of the end face of the first end 111 adjacent to the first end 111 , the first end 111 will Adhesive is accumulated between the part adjacent to the end face of the first end 111 and the first air-permeable seal, which will affect the cutting of the first air-permeable seal, reduce the cutting efficiency, and is easy to cut the first air-permeable seal. One end 111 is formed with burrs.

S12, put the first ends 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the first ends of the plurality of cooling pipes 11 The end faces of 111 are flush and adhered with adhesive.

S13 , providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal.

S14 , cutting the first air-permeable sealing member to form the first air-permeable sealing portion 12 for sealing the first end 111 .

S15 , filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the second end 112 .

S26, inverting the glue accumulating member.

S27, put the second end 112 into the accommodating space in the glue storage member, and contact with the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes 11 is The end surfaces of the two ends 112 are flush and adhered with adhesive.

S28, providing a second air-permeable seal, and attaching the end face of the second end 112 to which the adhesive is adhered to the second air-permeable seal.

S29 , cutting the second air-permeable sealing member to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 .

Among them, S11, S12, S13, S14, S15, S26, S27, S28 and S29 in this embodiment are the same as S11, S12, S13, S14, S15, S26, S27, S28 and S29 in the previous embodiment, It is not repeated here.

Please refer to FIG. 9 , which is a schematic flowchart of a method for preparing a cooling component according to another embodiment of the present application. In this embodiment, after the "turning over the glue accumulating member", in the "putting the second end 112 into the accommodating space in the glue accumulating member, and connecting with the accommodating space" Before contacting with the adhesive in the space, so that the end faces of the second ends 112 of the plurality of cooling pipes 11 are flush and adhered with the adhesive, the preparation method of the cooling assembly 10 further includes: The adhesive that exceeds the second preset height in the glue storage member is scraped off, and the range of the second preset height h2 is: 0.1mm≤h2≤0.3mm. It should be noted that this embodiment may be combined with any one of FIG. 5 or FIG. 8 for description. In this embodiment, the embodiment is combined with the embodiment in FIG. 8 for illustration, and FIG. 9 should not be construed as a Provided is the definition of the manufacturing method of the cooling assembly 10 .

Specifically, in this embodiment, the preparation method of the cooling assembly 10 includes but is not limited to S11, S31, S12, S13, S14, S15, S26, S32, S27, S28 and S29. Among them, S11, S31, S12, S13, S14, S15, S26, S27, S28 and S29 in this embodiment are the same as S11, S31, S12, S13, S14, S15, S26, S27, S28 in the previous embodiment Same as S29. Next, S11, S31, S12, S13, S14, S15, S26, S32, S27, S28 and S29 will be described in detail.

S11 , the preparation method of the cooling assembly 10 includes providing a plurality of cooling pipes 11 , the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113 .

S31 , scraping off the adhesive in the glue storage member that exceeds a first preset height, where the range of the first preset height h1 is: 0.1mm≤h1≤0.3mm.

S12, put the first ends 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the first ends of the plurality of cooling pipes 11 The end faces of 111 are flush and adhered with adhesive.

S13 , providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal.

S14 , cutting the first air-permeable sealing member to form the first air-permeable sealing portion 12 for sealing the first end 111 .

S15 , filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the second end 112 .

S26, inverting the glue accumulating member.

S32, scraping off the adhesive in the glue storage member that exceeds a second preset height, where the range of the second preset height h2 is: 0.1mm≤h2≤0.3mm.

Wherein, in this embodiment, by scraping off the adhesive that exceeds the second preset height in the glue storage member, the height of the binder in the accommodating space of the glue storage member is kept the same, thereby After the end surface of the second end 112 is immersed in the accommodating space and abuts the bottom of the gel storage member, the second ends 112 of the plurality of cooling pipes 11 can adhere to the same height of bonding agent. Therefore, the subsequent sticking process of the plurality of cooling tubes 11 can maintain the same quality, which improves the production quality of the cooling tubes 11. In addition, the range of the second preset height h2 is: 0.1mm≤h2≤0.3mm, which can ensure that the end face of the second end 112 can firmly fit the second breathable seal, and does not affect the first breathable seal. Two air-permeable seals are cut to form the second air-permeable seal portion 14 . If the second preset height h2 is too small, that is, too little adhesive adheres to the portion of the end face of the second end 112 adjacent to the second end 112 , the second end 112 The end face of the second breathable seal cannot be firmly fitted. If the second preset height h2 is too large, that is, too much adhesive adheres to the portion of the end surface of the second end 112 adjacent to the second end 112 , the second end 112 Adhesive is accumulated between the portion of the end face adjacent to the second end 112 and the second ventilating seal, which will affect the cutting of the second ventilating seal, reduce the cutting efficiency, and is easy to cut in the second ventilating seal. The two ends 112 are formed with burrs.

S27, put the second end 112 into the accommodating space in the glue storage member, and contact with the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes 11 is The end surfaces of the two ends 112 are flush and adhered with adhesive.

S28, providing a second air-permeable seal, and attaching the end face of the second end 112 to which the adhesive is adhered to the second air-permeable seal.

S29 , cutting the second air-permeable sealing member to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 .

Among them, S11, S31, S12, S13, S14, S15, S26, S27, S28 and S29 in this embodiment are different from S11, S31, S12, S13, S14, S15, S26, S27 and S28 in the previous embodiment. It is the same as S29 and will not be repeated here.

Please refer to FIG. 10 . FIG. 10 is a schematic flowchart of a method for preparing a first end with an adhesive in the method for preparing a cooling assembly provided by the embodiment of FIG. 1 . In this embodiment, the "putting the first end 111 into the accommodating space in the glue accumulator, and contacting the adhesive in the accommodating space, so that the plurality of cooling pipes "The end surface of the first end 111 of 11 is flush and adhered with an adhesive" includes disposing the glue accumulating member on one side of the first end 111 and being spaced from the first end 111 . The cooling tube 11 is pushed from the second end 112 to the first end 111 , and the magnitude F of the pushing force is: 1N≤F≤1.5N. and dipping the end face of the first end 111 into the adhesive in the accommodating space until the end face of the first end 111 abuts the glue accumulating member, so that the first end 111 is adjacent to the An adhesive is adhered to a portion of the end face of the first end 111 .

Specifically, in this embodiment, the "put the first end 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the multiple The end surfaces of the first ends 111 of each cooling pipe 11 are flush and adhered with an adhesive” specifically includes S121, S122 and S123. Next, S121, S122 and S123 will be described in detail.

S121 , disposing the glue accumulating member on one side of the first end 111 and at an interval from the first end 111 .

Wherein, in this embodiment, the glue accumulating member is arranged on one side of the first end 111, and the glue accumulating member is arranged at intervals on the first end 111 to ensure the adhesiveness in the accommodating space. The binder is spaced apart from the first end 111 .

S122 , the second end 112 pushes the cooling pipe 11 toward the first end 111 , and the magnitude F of the pushing force is: 1N≤F≤1.5N.

Wherein, in this embodiment, the cooling tube 11 is pushed toward the first end 111 by the second end 112, and the magnitude F of the pushing force is: 1N≤F≤1.5N. The first end 111 of the cooling pipe 11 can be pushed into the adhesive in the accommodating space, and the cooling pipe 11 will not be damaged due to excessive force. If the pushing force F is too small, the cooling pipe 11 cannot be pushed into the accommodating space, or the first end 111 of the cooling pipe 11 cannot be immersed in the adhesive in the accommodating space and The end surface of the first end 111 is made to abut the bottom surface of the glue accumulating member, so that the first end 111 of the cooling pipe 11 cannot fully adhere to the adhesive, so that the end surface of the first end 111 will be adhered to the subsequent end surface of the first end 111. The result is that the first breathable seal is not strong enough. If the pushing force F is too large, the cooling pipe 11 will be easily pushed into the accommodating space, and the first end 111 of the cooling pipe 11 is immersed in the adhesive in the accommodating space. Afterwards, the end face of the first end 111 will abut against the bottom surface of the glue accumulator, but because the pushing force F is too large, the end face of the first end 111 has the risk of hitting the bottom face of the glue accumulator. The first end 111 is damaged. Therefore, the force F that pushes the first end 111 of the cooling tube 11 into the adhesive in the accommodating space needs to be kept moderately large. In this embodiment, the force F for pushing is: 1N≤ F≤1.5N. In one embodiment, a pressing plate is used to act on the end face of the second end 112 to push the cooling tube 11 . In another embodiment, a pressing rod is used to act on the end face of the second end 112 to push the cooling tube 11 . In other embodiments, a pressing block or other components with driving force may be used to act on the second end 112, as long as a force of magnitude F can be provided to act on the second end 112, and the The first ends 111 of the cooling pipes 11 are put into the accommodating space in the gel storage member, and contact with the adhesive in the accommodating space, so that the first ends 111 of the plurality of cooling pipes 11 The end face is flush and the adhesive is attached.

S123, immerse the end face of the first end 111 into the adhesive in the accommodating space until the end face of the first end 111 abuts the glue accumulating member, so that the first end 111 is adjacent to the An adhesive is adhered to a portion of the end face of the first end 111 .

Wherein, in this embodiment, the end face of the first end 111 abuts the glue accumulating member, specifically, the end face of the first end 111 abuts the bottom surface of the glue accumulating member, so that the first end 111 abuts the bottom surface of the glue accumulating member The end 111 can sufficiently contact the adhesive in the accommodating space, so that the end surface of the first end 111 and the part of the end surface of the first end 111 adjacent to the first end 111 are adhered with the adhesive, Thus, it is ensured that when the end face of the first end 111 is subsequently bonded to the first air-permeable seal, the end face of the first end 111 and the first air-permeable seal can be sufficiently firmly bonded. In addition, the end surfaces of the first ends 111 of the plurality of cooling pipes 11 are in contact with the bottom surface of the gel storage member, which can ensure that the first ends 111 of the plurality of cooling pipes 11 are adhered to the same degree of adhesive. Conducive to ensuring production quality.

Please refer to FIG. 11 . FIG. 11 is a schematic flowchart of a method for preparing a second end with an adhesive in the method for preparing a cooling assembly provided by the embodiment of FIG. 5 . In this embodiment, the "putting the second end 112 into the accommodating space in the glue accumulating member, and contacting the adhesive in the accommodating space, so that the plurality of cooling pipes “The end face of the second end 112 of 11 is flush and adhered with an adhesive” includes disposing the glue accumulating member on one side of the second end 112 and being spaced from the second end 112 . The cooling tube 11 is pushed from the first end 111 to the second end 112 , and the magnitude F of the pushing force is: 1N≤F≤1.5N. and dipping the end face of the second end 112 into the adhesive in the accommodating space until the end face of the second end 112 abuts the glue accumulating member, so that the second end 112 is adjacent to the A portion of the end face of the second end 112 is adhered with adhesive.

Specifically, in this embodiment, "put the second end 112 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the multiple The end surfaces of the second ends 112 of each cooling pipe 11 are flush and adhered with an adhesive” specifically includes S271, S272 and S273. Next, S271, S272 and S273 will be described in detail.

S271 , disposing the glue accumulating member on one side of the second end 112 and at an interval from the second end 112 .

Wherein, in this embodiment, the glue accumulating member is arranged on one side of the second end 112, and the glue accumulating member is arranged at intervals at the second end 112 to ensure the adhesiveness in the accommodating space. The cement is spaced from the second end 112 .

S272 , the second end 112 pushes the cooling pipe 11 toward the first end 111 , and the magnitude F of the pushing force is: 1N≤F≤1.5N.

Wherein, in this embodiment, the cooling tube 11 is pushed toward the second end 112 through the first end 111, and the magnitude F of the pushing force is: 1N≤F≤1.5N. The second end 112 of the cooling pipe 11 can be pushed into the adhesive in the accommodating space, and the cooling pipe 11 will not be damaged due to excessive force. If the pushing force F is too small, the cooling pipe 11 cannot be pushed into the accommodating space, or the second end 112 of the cooling pipe 11 cannot be immersed in the adhesive in the accommodating space and The end surface of the second end 112 is made to abut the bottom surface of the glue accumulating member, so that the second end 112 of the cooling pipe 11 cannot be fully adhered to the adhesive, so that the end surface of the second end 112 will be adhered. Knot the second breathable seal is not strong enough. If the pushing force F is too large, the cooling pipe 11 will be easily pushed into the accommodating space, and the second end 112 of the cooling pipe 11 is immersed in the adhesive in the accommodating space. Afterwards, the end face of the second end 112 will abut against the bottom surface of the glue accumulator, but because the pushing force F is too large, the end face of the second end 112 has the risk of hitting the bottom face of the glue accumulator. The second end 112 is damaged. Therefore, the force F that pushes the second end 112 of the cooling pipe 11 into the adhesive in the accommodating space needs to be kept at a moderate level. In this embodiment, the force F for pushing is: 1N≤ F≤1.5N. In one embodiment, a pressing plate is used to act on the end surface of the first end 111 to push the cooling tube 11 . In another embodiment, a pressing rod is used to act on the end face of the first end 111 to push the cooling pipe 11 . In other embodiments, a pressing block or other components with driving force can be used to act on the first end 111, as long as a force of magnitude F can be provided to act on the first end 111, and the The second ends 112 of the cooling pipes 11 are put into the accommodating space in the gel storage member, and contact with the adhesive in the accommodating space, so that the second ends 112 of the plurality of cooling pipes 11 The end face is flush and the adhesive is attached.

S273, immerse the end face of the second end 112 into the adhesive in the accommodating space until the end face of the second end 112 abuts the glue accumulating member, so that the second end 112 is adjacent to the An adhesive is adhered to a portion of the end face of the second end 112 .

Wherein, in this embodiment, the end face of the second end 112 abuts against the glue storage member, specifically, the end face of the second end 112 abuts against the bottom surface of the glue storage member, so that the second end 112 abuts against the bottom surface of the glue storage member. The end 112 can sufficiently contact the adhesive in the accommodating space, so that the end surface of the second end 112 and the part of the end surface of the second end 112 adjacent to the second end 112 are adhered with the adhesive, Thus, it is ensured that when the end face of the second end 112 is subsequently bonded to the second breathable sealing member, the end face of the second end 112 and the second breathable sealing member can be sufficiently firmly bonded. In addition, the end surfaces of the second ends 112 of the plurality of cooling pipes 11 abut against the bottom surface of the gel storage member, which can ensure that the second ends 112 of the plurality of cooling pipes 11 adhere to the same degree of adhesive. Conducive to ensuring production quality.

Please refer to FIGS. 12 and 13 , FIG. 12 is a schematic flowchart of a method for preparing a cooling assembly provided by another embodiment of the present application; FIG. 13 is a first breathable sealing portion prepared by the method for preparing a cooling assembly according to the embodiment of FIG. 12 . Schematic diagram of the structure. In this embodiment, after the "providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal", in the " Before cutting the first breathable sealing member to form the first breathable sealing portion 12 ″ sealing the first end 111 , the preparation method of the cooling assembly 10 further includes cutting the first breathable sealing member with the first breathable sealing member 12 ″. The first ventilation hole 121 is formed by cutting the area surrounded by the end face of the first end 111 . It should be noted that this embodiment may be combined with any one of FIG. 1 or FIG. 5 for description. In this embodiment, the embodiment is combined with the embodiment in FIG. 5 for illustration, and FIG. 12 should not be construed as a reference to this application Provided is the definition of the manufacturing method of the cooling assembly 10 .

Specifically, in this embodiment, the preparation methods of the cooling assembly 10 include but are not limited to S11, S12, S13, S41, S14, S15, S26, S27, S28 and S29. Among them, S11 , S12 , S13 , S14 , S15 , S26 , S27 , S28 and S29 in this embodiment are the same as S11 , S12 , S13 , S14 , S15 , S26 , S27 , S28 and S29 in the foregoing embodiment. Next, S11, S12, S13, S41, S14, S15, S26, S27, S28 and S29 will be described in detail.

S11 , the preparation method of the cooling assembly 10 includes providing a plurality of cooling pipes 11 , the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113 .

S12, put the first ends 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the first ends of the plurality of cooling pipes 11 The end faces of 111 are flush and adhered with adhesive.

S13 , providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal.

S41 , cutting the area surrounded by the part of the first ventilating seal and the end surface of the first end 111 that is in contact with the first ventilating hole 121 .

Wherein, in this embodiment, the area surrounded by the part where the first air-permeable sealing member and the end face of the first end 111 fit together refers to the location where the first air-permeable sealing part 12 formed in the subsequent step S14 is located. area. In this embodiment, the number of the first ventilation holes 121 is one or more, and the shape of the first ventilation holes 121 may be, but not limited to, a circle, a rectangle, a polygon, or an irregular shape. The first ventilation holes 121 can increase the air permeability of the cooling tube 11 , thereby reducing the resistance of the aerosol flowing through the cooling tube 11 to reduce the suction resistance. It should be noted that the size of the first ventilation hole 121 is smaller than the size of the cooling material in the cooling part 13 to prevent the cooling material in the cooling part 13 from leaking out of the first ventilation hole 121 .

S14 , cutting the first air-permeable sealing member to form the first air-permeable sealing portion 12 for sealing the first end 111 .

S15 , filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the second end 112 .

S26, inverting the glue accumulating member.

S27, put the second end 112 into the accommodating space in the glue storage member, and contact with the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes 11 is The end surfaces of the two ends 112 are flush and adhered with adhesive.

S28, providing a second air-permeable seal, and attaching the end face of the second end 112 to which the adhesive is adhered to the second air-permeable seal.

S29 , cutting the second air-permeable sealing member to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 .

S11 , S12 , S13 , S14 , S15 , S26 , S27 , S28 and S29 in this embodiment are the same as S11 , S12 , S13 , S14 , S15 , S26 , S27 , S28 and S29 in the previous embodiment, and are not omitted here. Repeat.

Please refer to FIG. 14 . FIG. 14 is a schematic flowchart of a method for preparing a first ventilation hole provided in an embodiment of the method for preparing a cooling component provided in the embodiment of FIG. 12 . In this embodiment, the “cutting the area surrounded by the part of the first air-permeable seal and the end surface of the first end 111 that is in contact with the end surface of the first end 111 to form the first air-permeable hole 121” includes selecting the first air-permeable seal. A predetermined area in the area surrounded by the part of the breathable seal that is in contact with the end face of the first end 111 . and cutting the outer contour of the preset area to form the first ventilation hole 121 .

Specifically, in this embodiment, the “cutting the area surrounded by the part of the first air-permeable seal and the end surface of the first end 111 that is in contact with the end surface of the first end 111 to form the first air-permeable hole 121 ” includes S411 and S412 . Next, S411 and S412 will be described in detail.

S411 , selecting a preset area in the area surrounded by the part of the first air-permeable seal and the end surface of the first end 111 that is in contact with each other.

Wherein, in this embodiment, the number of the preset area is one or more, and the shape of the preset area may be, but not limited to, a circle, a rectangle, a polygon, or an irregular shape.

S412 , cutting the outer contour of the preset area to form the first ventilation hole 121 .

Wherein, in this embodiment, the first ventilating seal is cut along the outer contour of the preset area to form the first ventilating hole 121 . Specifically, the first air-permeable seal is cut by a laser, the first air-permeable seal is cut along the outer contour of the preset area by the laser emitted by the laser head, and the laser emitted by the laser head is used to cut the first air-permeable seal Translation and rotation may cut a plurality of the first breathable seals. Since the laser has high energy, the energy can be transferred to the first air-permeable seal, so that the place on the first air-permeable seal irradiated by the laser generates high temperature and burns. Also, because the diameter of the light spot irradiated by the laser light on the first air-permeable seal is in the order of micrometers and can be approximated as a point, the paths irradiated by the laser on the first air-permeable seal are connected to be approximated as lines. When the laser moves along the outer contour of the preset area on the first air-permeable seal, the laser will burn each point on the outer contour of the preset area to form micron-level holes. The holes are connected to form an incision, so that the first preset area falls off to form the first ventilation hole 121, and the laser is used to cut along the outer contour of the preset area, and the cutting speed is fast. Specifically, the power P1 of the device carrying the laser head is: 60W≤P1≤150W, and the power P2 of the laser head when working is: P1*60%≤P2≤P1*80%, the laser head emits The moving speed v1 of the laser is: 800mm/s≤v1≤1500mm/s, and the focal length d1 of the laser emitted by the laser head is: 30cm≤d1≤60cm. It should be noted that, in one embodiment, the laser head is fixed, and cutting is performed only by the translation and rotation of the laser light emitted by the laser head. In another embodiment, the movement of the laser emitted by the laser head is driven to perform cutting through the translation and rotation of the laser head. In this embodiment, the laser head is fixed, and only cutting is performed by the translation and rotation of the laser emitted by the laser head for exemplary illustration.

Please refer to FIG. 15 . FIG. 15 is a schematic flowchart of a method for preparing a first ventilation hole provided by another embodiment of the method for preparing a cooling component provided in the embodiment of FIG. 12 . In this embodiment, the "cutting the area surrounded by the part of the first air-permeable seal and the end surface of the first end 111 in contact with the end surface of the first end 111 to form the first air-permeable hole 121" includes selecting a preset area. and cutting the inside of the preset area to form the first ventilation hole 121 .

Specifically, in this embodiment, the “cutting the area surrounded by the part of the first air-permeable seal and the end surface of the first end 111 that fits together to form the first air-permeable hole 121” includes S413 and S414 . Next, S413 and S414 will be described in detail.

S413 , selecting a preset area in the area surrounded by the portion of the first air-permeable seal and the end surface of the first end 111 that is in contact with each other.

Wherein, in this embodiment, the number of the preset area is one or more, and the shape of the preset area may be, but not limited to, a circle, a rectangle, a polygon, or an irregular shape.

S414 , cutting the inside of the preset area to form the first ventilation hole 121 .

In this embodiment, since the laser has high energy, the energy can be transferred to the first air-permeable seal, so that the place irradiated by the laser on the first air-permeable seal generates high temperature and burns . By irradiating each point on the preset area with laser light, the preset area is completely burned, so as to form the first ventilation hole 121, and no shedding waste will be generated, and only the first ventilation hole 121 needs to be drawn away by a fan. The fumes from the combustion of the breathable seal do not require further disposal of waste chips, simplifying the machining process. Specifically, the power P1 of the device carrying the laser head is: 60W≤P1≤150W, and the power P2 of the laser head when working is: P1*60%≤P2≤P1*80%, the laser head emits The moving speed v1 of the laser is: 800mm/s≤v1≤1500mm/s, and the focal length d1 of the laser emitted by the laser head is: 30cm≤d1≤60cm. It should be noted that, in one embodiment, the laser head is fixed, and cutting is performed only by the translation and rotation of the laser light emitted by the laser head. In another embodiment, the movement of the laser emitted by the laser head is driven to perform cutting through the translation and rotation of the laser head. In this embodiment, the laser head is fixed, and only cutting is performed by the translation and rotation of the laser emitted by the laser head for exemplary illustration.

In one embodiment, the spot size of the laser remains unchanged, and the laser irradiates the entire preset area along the upper end of the outer contour of the preset area to the other end of the outer contour of the preset area, so as to The entire predetermined area is burned to form the first ventilation hole 121 .

In another embodiment, the spot size of the laser remains unchanged, and the laser irradiates the entire preset area from the inside of the preset area to the outer contour of the preset area, so as to irradiate the entire preset area Burn off to form the first ventilation hole 121 .

In yet another embodiment, the spot size of the laser is adjusted, and when the laser irradiates the interior of the preset area, the spot size of the laser is increased to speed up the speed of the laser cutting the preset area. When the laser irradiates the area near the outer contour of the preset area, the spot size of the laser is reduced to prevent the laser from cutting to areas outside the preset area.

Please refer to FIGS. 16 and 17 , FIG. 16 is a schematic flowchart of a method for preparing a cooling assembly provided by another embodiment of the present application; FIG. 17 is a second breathable sealing portion prepared by the method for preparing a cooling assembly according to the embodiment of FIG. 16 . Schematic diagram of the structure. In this embodiment, after the “providing a second air-permeable seal, and attaching the end face of the second end 112 to which the adhesive is adhered to the second air-permeable seal”, in the “ Before cutting the second air-permeable seal to form the second air-permeable seal portion 14 ″ for sealing the second end 112 , the preparation method of the cooling assembly 10 further includes assembling the second air-permeable seal with the second air-permeable seal. The area surrounded by the end face of the second end 112 is cut to form the second ventilation hole 141 . It should be noted that this embodiment can be combined with any one of FIG. 5 or FIG. 12 for illustration. In this embodiment, it is combined with the embodiment in FIG. 12 for illustration, and FIG. 15 should not be construed as a Provided is the definition of the manufacturing method of the cooling assembly 10 .

Specifically, in this embodiment, the preparation method of the cooling assembly 10 includes but is not limited to S11, S12, S13, S41, S14, S15, S26, S27, S28, S42 and S29. Among them, S11, S12, S13, S41, S14, S15, S26, S27, S28 and S29 in this embodiment are the same as S11, S12, S13, S41, S14, S15, S26, S27, S28 and Same for S29. Next, S11, S12, S13, S41, S14, S15, S26, S27, S28, S42 and S29 will be described in detail.

S11 , the preparation method of the cooling assembly 10 includes providing a plurality of cooling pipes 11 , the cooling pipes 11 include a first end 111 and a second end 112 arranged opposite to each other, and the cooling pipes 11 have a receiving space 113 .

S12, put the first ends 111 into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the first ends of the plurality of cooling pipes 11 The end faces of 111 are flush and adhered with adhesive.

S13 , providing a first air-permeable seal, and attaching the end face of the first end 111 to which the adhesive is adhered to the first air-permeable seal.

S41, cutting the area surrounded by the part of the first air-permeable seal and the end face of the first end that fits together to form a first air-permeable hole 121.

S14 , cutting the first air-permeable sealing member to form the first air-permeable sealing portion 12 for sealing the first end 111 .

S15 , filling the cooling part 13 into the receiving space 113 of the cooling pipe 11 from the first end 111 .

S26, inverting the glue accumulating member.

S27, put the second end 112 into the accommodating space in the glue storage member, and contact with the adhesive in the accommodating space, so that the first end of the plurality of cooling pipes 11 is The end surfaces of the two ends 112 are flush and adhered with adhesive.

S28, providing a second air-permeable seal, and attaching the end face of the second end 112 to which the adhesive is adhered to the second air-permeable seal.

S42 , cutting the area surrounded by the part of the second air-permeable seal and the end surface of the second end 112 to form a second air-permeable hole 141 .

Wherein, in this embodiment, the area surrounded by the part where the second air-permeable sealing member and the end face of the second end 112 fit together refers to the location where the second air-permeable sealing portion 14 formed in the subsequent step S29 is located. area. In this embodiment, the number of the second ventilation holes 141 is one or more, and the shape of the second ventilation holes 141 may be, but not limited to, a circle, a rectangle, a polygon, or an irregular shape. The second ventilation holes 141 can increase the air permeability of the cooling tube 11 , thereby reducing the resistance of the aerosol flowing through the cooling tube 11 to reduce the suction resistance. It should be noted that the size of the second ventilation hole 141 is smaller than the size of the cooling material in the cooling part 13 to prevent the cooling material in the cooling part 13 from leaking out of the second ventilation hole 141 .

S29 , cutting the second air-permeable sealing member to form a second air-permeable sealing portion 14 that seals the end face of the second end 112 .

S11, S12, S13, S41, S14, S15, S26, S27, S28 and S29 in this embodiment are the same as S11, S12, S13, S41, S14, S15, S26, S27, S28 and S29 in the previous embodiment , and will not be repeated here.

Please refer to FIG. 18 . FIG. 18 is a schematic flowchart of a method for preparing a second ventilation hole provided by an embodiment in the method for preparing a cooling component provided by the embodiment of FIG. 16 . In this embodiment, the “cutting the area surrounded by the part of the second ventilating seal and the end face of the second end 112 that is in contact with the end surface of the second end 112 to form the second venting hole 141” includes selecting the second ventilating hole 141 . A predetermined cutting area in the area surrounded by the portion of the air-permeable seal that is in contact with the end face of the second end 112 . And the outer contour of the preset cutting area is cut to form the second ventilation hole 141 .

Specifically, in this embodiment, the "cutting the area surrounded by the part of the second ventilating seal and the end surface of the second end 112 that is in contact with the end surface of the second end 112 to form the second vent hole 141" includes S421 and S422 . Next, S421 and S422 will be described in detail.

S421 , selecting a preset cutting area in the area surrounded by the part of the second air-permeable seal and the end surface of the second end 112 .

Wherein, in this embodiment, the number of the preset cutting regions is one or more, and the shape of the preset cutting regions may be, but not limited to, a circle, a rectangle, a polygon, or an irregular shape.

S422 , cutting the outer contour of the preset cutting area to form second ventilation holes 141 .

Wherein, in this embodiment, the second ventilating seal is cut along the outer contour of the preset cutting area to form the second venting hole 141 . Specifically, the second air-permeable seal is cut by a laser, the second air-permeable seal is cut along the outer contour of the preset cutting area by the laser emitted by the laser head, and the laser emitted by the laser head is used to cut the second air-permeable seal. The translation and rotation of a plurality of the second gas permeable seals can be cut. Since the laser has relatively high energy, the energy can be transferred to the second air-permeable sealing member, so that the place irradiated by the laser on the second air-permeable sealing member generates high temperature and burns. Also, because the diameter of the light spot irradiated by the laser on the second air-permeable seal is in the order of micrometers and can be approximated as a point, the paths irradiated by the laser on the second air-permeable seal are connected to be approximated as lines. When the laser moves along the outer contour of the preset cutting area on the second air-permeable seal, the laser will burn each point on the outer contour of the preset cutting area to form micron-level holes, which are The holes formed by burning are connected to form an incision, so that the first preset cutting area falls off to form the second ventilation hole 141, and the laser is used to cut along the outer contour of the preset cutting area, and the cutting speed is fast . Specifically, the power P3 of the device carrying the laser head is: 60W≤P3≤150W, and the power P4 of the laser head when working is: P3*60%≤P4≤P3*80%, the laser head emits The moving speed v2 of the laser is: 800mm/s≤v2≤1500mm/s, and the focal length d2 of the laser emitted by the laser head is: 30cm≤d2≤60cm. It should be noted that, in one embodiment, the laser head is fixed, and cutting is performed only by the translation and rotation of the laser light emitted by the laser head. In another embodiment, the movement of the laser emitted by the laser head is driven to perform cutting through the translation and rotation of the laser head. In this embodiment, the laser head is fixed, and only cutting is performed by the translation and rotation of the laser emitted by the laser head for exemplary illustration.

Please refer to FIG. 19 . FIG. 19 is a schematic flowchart of a method for preparing a second ventilation hole provided by another embodiment in the method for preparing a cooling component provided in the embodiment of FIG. 16 . In this embodiment, the "cutting the area surrounded by the part of the second ventilating seal and the end surface of the second end 112 that is in contact with the end surface of the second end 112 to form the second venting hole 141" includes selecting a preset cutting area . And the inside of the preset cutting area is cut to form the second ventilation hole 141 .

Specifically, in this embodiment, the “cutting the area surrounded by the part of the second air-permeable seal and the end surface of the second end 112 that fits together to form the second air-permeable hole 141” includes S423 and S424 . Next, S423 and S424 will be described in detail.

S423 , selecting a preset cutting area in the area surrounded by the part of the second air-permeable seal and the end surface of the second end 112 that is in contact with each other.

Wherein, in this embodiment, the number of the preset cutting regions is one or more, and the shape of the preset cutting regions may be, but not limited to, a circle, a rectangle, a polygon, or an irregular shape.

S424 , cutting the inside of the preset cutting area to form the second ventilation hole 141 .

Among them, in this embodiment, the laser has high energy, so the energy can be transferred to the second air-permeable sealing member, so that the place irradiated by the laser on the second air-permeable sealing member generates high temperature and burns . By irradiating each point on the preset cutting area with laser light, the preset cutting area is completely burned, so as to form the second ventilation hole 141, and no shedding waste will be generated, and only the fan needs to be used to remove the The smoke generated by the combustion of the second vent seal does not need to be further processed for waste chips, which simplifies the processing procedure. Specifically, the power P3 of the device carrying the laser head is: 60W≤P1≤150W, and the power P4 of the laser head when working is: P3*60%≤P4≤P3*80%, the laser head emits The moving speed v2 of the laser is: 800mm/s≤v2≤1500mm/s, and the focal length d2 of the laser emitted by the laser head is: 30cm≤d2≤60cm. It should be noted that, in one embodiment, the laser head is fixed, and cutting is performed only by the translation and rotation of the laser light emitted by the laser head. In another embodiment, the movement of the laser emitted by the laser head is driven to perform cutting through the translation and rotation of the laser head. In this embodiment, the laser head is fixed, and only cutting is performed by the translation and rotation of the laser emitted by the laser head for exemplary illustration.

In one embodiment, the spot size of the laser remains unchanged, and the laser irradiates the entire preset cutting area along the upper end of the outer contour of the preset cutting area to the other end on the outer contour of the preset cutting area , so as to burn off the entire preset cutting area to form the second ventilation hole 141 .

In another embodiment, the spot size of the laser remains unchanged, and the laser irradiates the entire preset cutting area from the inside of the preset cutting area to the outer contour of the preset cutting area, so that the entire The predetermined cutting area is burnt out to form the second ventilation hole 141 .

In yet another embodiment, the spot size of the laser is adjusted, and when the laser irradiates the interior of the preset cutting area, the spot size of the laser is increased to speed up the speed of the laser cutting the preset cutting area. When the laser irradiates the area near the outer contour of the preset cutting area, the spot size of the laser is reduced to prevent the laser from cutting to areas outside the preset cutting area.

Please refer to FIG. 20 and FIG. 21 , FIG. 20 is a schematic flowchart of a method for preparing a HNB cartridge provided by an embodiment of the application; FIG. 21 is prepared by the method for preparing a HNB cartridge provided by the embodiment of FIG. 20 Schematic diagram of the structure of a heat-not-burn pod. The preparation method of the heat not burn pod 1 includes providing a tube body 20 , and the tube body 20 has an accommodating space 21 . One end of the tubular body 20 is sealed with a sealing member 30 . The smoking member 40 is installed into the accommodating space 21 from the end away from the sealing member 30 , and the smoking member 40 is adjacent to the sealing member 30 . The cooling assembly 10 prepared by the method for preparing the cooling assembly 10 according to any one of the foregoing embodiments is loaded into the accommodating space 21 from the end away from the sealing member 30 , and the first end 111 is opposite to the The second end 112 is disposed adjacent to the smoking member 40 . And the filter element 50 is loaded into the accommodating space 21 from the end away from the sealing element 30 .

In this embodiment, the method for preparing the HNB pod 1 includes but is not limited to S51, S52, S53, S54 and S55. Next, S51, S52, S53, S54, and S55 will be described in detail.

S51 , providing the tube body 20 , the tube body 20 having the accommodating space 21 .

Wherein, in this embodiment, the tube body 20 is an edible-grade material, so the tube body 20 can reduce or even not generate harmful substances when heated. For example, the tube body 20 may be, but not limited to, food-grade materials such as white cardboard or kraft paper. Specifically, the tube body 20 may be, but not limited to, food-grade materials such as white cardboard of 50-200 g/m2 or kraft paper of 50-200 g/m2.

S52 , sealing one end of the tube body 20 with the sealing member 30 .

Wherein, in this embodiment, the sealing member 30 is a food-grade material, so the sealing member 30 can reduce or even not generate harmful substances when heated. For example, the sealing member 30 may be, but not limited to, food-grade materials such as silk cotton paper, high-air permeability paper, or tallow paper. Specifically, the sealing member 30 may be, but not limited to, edible-grade materials such as 10-50 g/m2 silk tissue paper, 10-50 g/m2 high air permeability paper, or 45-105 g/m2 tallow paper.

S53 , the smoking member 40 is loaded into the accommodating space 21 from the end away from the sealing member 30 , and the smoking member 40 is adjacent to the sealing member 30 .

Wherein, in this embodiment, the smoking member 40 is provided with an aerosol matrix, and the aerosol matrix may be, but not limited to, a mixture of one or more of herbs, Chinese herbal medicines or tobacco leaves. When the smoking element 40 is heated, the aerosol matrix in the smoking element 40 is heated to generate an aerosol matrix.

S54, load the cooling assembly 10 prepared by the method for preparing the cooling assembly 10 according to any one of the foregoing embodiments into the accommodating space 21 from the end away from the sealing member 30, and make the first end 111 relative to the accommodating space 21. The second end 112 is disposed adjacent to the smoking member 40 .

Wherein, in this embodiment, the cooling component 10 is used for cooling the aerosol generated by the heating of the aerosol matrix in the smoking component, so as to cool the aerosol to a temperature suitable for smoking. In this embodiment, the first end 111 is disposed adjacent to the smoking member 40 relative to the second end 112 , and the first air-permeable sealing portion 12 in the cooling assembly 10 can prevent the cooling portion 13 is dropped into the smoking member 40 to mix with the aerosol-forming substrate in the smoking member 40. For the preparation method of the cooling assembly 10, please refer to any one of the foregoing embodiments, and details are not repeated here.

S55 , the filter element 50 is loaded into the accommodating space 21 from the end away from the sealing element 30 .

Wherein, in this embodiment, the filter element 50 is used to filter the aerosol cooled by the cooling component 10 to filter impurities in the aerosol, so as to improve the fineness of the aerosol.

In this embodiment, since the cooling assembly 10 can seal a plurality of the cooling tubes 11 at one time, and then cut along the outer contour of the cooling tubes 11, the cooling assembly 10 is formed. Therefore, the production efficiency of the cooling component 10 in the method for preparing the HNB pod 1 provided by this embodiment is high, and the production efficiency of the HNB pod 1 is improved.

Please refer to FIGS. 22 , 23 and 24 together. FIG. 22 is a schematic structural diagram of a cooling assembly provided by an embodiment of the application; FIG. 23 is an enlarged schematic view of part I in the cooling assembly provided by the embodiment of FIG. 22 ; FIG. 24 is a FIG. 22 is an enlarged schematic view of the position II in the cooling assembly provided by the embodiment. The cooling assembly 10 includes a cooling pipe 11 and a cooling portion 13 . The cooling pipe 11 includes a first end 111 and a second end 112 disposed opposite to each other, and the cooling pipe 11 has a receiving space 113 . The cooling portion 13 is accommodated in the accommodating space 113 , and the volume ratio a of the cooling portion 13 to the accommodating space 113 is 20%≦a≦60%. The cooling assembly 10 further includes a first adhesive layer 15 and a first air-permeable sealing portion 12 . And/or, the cooling assembly 10 further includes a second adhesive layer 16 and a second air-permeable sealing portion 14 . When the cooling element 10 includes the first adhesive layer 15 and the first air-permeable sealing portion 12 , the first adhesive layer 15 is disposed on the end surface of the first end 111 and is located adjacent to the first end 111 . The portion of the end face of the first end 111 is described. The first air-permeable sealing portion 12 is bonded to the end surface of the first end 111 through the first adhesive layer 15 . When the cooling element 10 includes the second adhesive layer 16 and the second air-permeable sealing portion 14 , the second adhesive layer 16 is disposed on the end surface of the second end 112 and is located adjacent to the second end 112 . The portion of the end face of the second end 112 is described. The second air-permeable sealing portion 14 is bonded to the end surface of the second end 112 through the second adhesive layer 16 .

In this embodiment, the range of the volume ratio a of the cooling portion 13 to the storage space 113 is: 20%≦a≦60%, so that the cooling efficiency of the cooling portion 13 can be maintained. The cooling assembly 10 has suitable suction resistance. If the volume ratio a of the cooling part 13 to the accommodation space 113 is too large, the resistance of the aerosol passing through the cooling part 13 will increase, thereby making the suction resistance too large. If the volume ratio a of the cooling portion 13 to the receiving space 113 is too small, the contact area between the cooling portion 13 and the aerosol will be reduced, thereby reducing the cooling effect of the cooling portion 13 .

In this embodiment, when the cooling element 10 includes a first adhesive layer 15 and a first air-permeable sealing portion 12 , the first adhesive layer 15 is disposed on the end face of the first end 111 and located in the The first end 111 is adjacent to the end face of the first end 111, and the height h3 of the first adhesive layer 15 at the portion of the first end 111 adjacent to the end face of the first end 111 is: 0.1 mm ≤h3≤0.3mm. The first air-permeable sealing portion 12 is bonded to the end surface of the first end 111 through the first adhesive layer 15 . In this embodiment, the first adhesive layer 15 is a food-grade adhesive, which can reduce or even not produce poison when heated. For example, the first adhesive layer 15 may be, but is not limited to, one or more food-grade adhesives selected from glutinous rice glue, lap glue, straw glue, white latex, and the like. The first adhesive layer 15 increases the strength of the end face of the first end 111 and the portion of the first end 111 adjacent to the end face of the first end 111 , so that the first end of the cooling pipe 11 is strengthened. The end face of 111 can withstand greater pressure, which reduces or even eliminates the damage of the cooling assembly 10 caused by the pressure during the processing, and reduces or even eliminates the application of the cooling assembly 10 for heating When the non-combustible cartridge 1 is inserted into the smoking device, the cooling assembly 10 is damaged due to pressure. Since the first adhesive layer 15 may produce peculiar smell when heated, in this embodiment, the first adhesive layer 15 is subjected to a baking process to remove the peculiar smell in the first adhesive layer 15 , so that the cooling assembly 10 will not produce peculiar smell when it is heated in the heat-not-burn pod 1, and the moisture in the first adhesive layer 15 is further reduced by the baking treatment, so that the first adhesive The junction layer 15 is cured, which further enhances the bonding strength between the first adhesive layer 15 and the end face of the first end 111 . In addition, the height h3 of the first adhesive layer 15 can ensure that the end surface of the first end 111 can firmly fit the first air-permeable sealing portion 12 without affecting the end surface of the first end 111 and the The flatness of the bonding portion of the first breathable sealing portion 12 . If the height h3 is too small, that is, too little adhesive is adhered to the end surface of the first end 111 adjacent to the first end 111 , the end surface of the first end 111 cannot be firmly adhered to Fit the first breathable sealing part 12 . If the height h3 is too large, that is, too much adhesive is adhered to the portion of the end face of the first end 111 adjacent to the first end 111, so that the first end 111 is adjacent to the first end 111. Adhesive is deposited between the end face of one end 111 and the first air-permeable sealing part 12 , which increases the thickness of the first air-permeable sealing part 12 that needs to be cut during the cutting process, thereby affecting the The cutting process of the first air-permeable sealing part 12 is easy to form burrs at the joint of the first air-permeable sealing part 12 and the end surface of the first end 111 during the cutting process of the first air-permeable sealing part 12 .

In this embodiment, when the cooling assembly 10 further includes a second adhesive layer 16 and a second air-permeable sealing portion 14 , the second adhesive layer 16 is disposed on the end surface of the second end 112 and is located at the end of the second end 112 . The second end 112 is adjacent to the end face of the second end 112, and the height h4 of the second adhesive layer 16 at the portion of the second end 112 adjacent to the end face of the second end 112 is: 0.1 mm≤h4≤0.3mm. The second air-permeable sealing portion 14 is bonded to the end surface of the second end 112 through the second adhesive layer 16 . In this embodiment, the second adhesive layer 16 is a food-grade adhesive, which can reduce or even not produce poison when heated. For example, the second adhesive layer 16 can be, but is not limited to, one or more food-grade adhesives selected from glutinous rice glue, lap glue, straw glue, white latex, and the like. The second adhesive layer 16 increases the strength of the end face of the second end 112 and the portion of the second end 112 adjacent to the end face of the second end 112 , so that the second end of the cooling pipe 11 is strengthened. The end face of 112 can withstand greater pressure, which reduces or even eliminates the damage of the cooling assembly 10 caused by the pressure during processing, and reduces or even eliminates the application of the cooling assembly 10 for heating When the non-combustible cartridge 1 is inserted into the smoking device, the cooling assembly 10 is damaged due to pressure. Since the second adhesive layer 16 may produce peculiar smell when heated, in this embodiment, the second adhesive layer 16 is subjected to a baking process to remove the peculiar smell in the second adhesive layer 16 , so that the cooling assembly 10 will no longer produce peculiar smell when it is heated in the heat-not-burn pod 1, and the moisture in the second adhesive layer 16 is further reduced by the baking treatment, so that the second adhesive layer 16 is further reduced. The junction layer 16 is cured, which further enhances the bonding strength between the second adhesive layer 16 and the end face of the second end 112 . In addition, the height h4 of the second adhesive layer 16 can ensure that the end surface of the second end 112 can firmly fit the second air-permeable sealing portion 14 without affecting the end surface of the second end 112 and the The flatness of the bonding portion of the second air-permeable sealing portion 14 . If the height h4 is too small, that is, too little adhesive is adhered to the end surface of the second end 112 adjacent to the second end 112 , so that the end surface of the second end 112 cannot be firmly adhered to Fit the second breathable sealing part 14 . If the height h4 is too large, that is, too much adhesive is adhered to the portion of the end surface of the second end 112 adjacent to the second end 112, so that the second end 112 is adjacent to the first end 112. Adhesive is deposited between the end surfaces of the two ends 112 and the second air-permeable sealing part 14 , which increases the thickness of the second air-permeable sealing part 14 that needs to be cut during the cutting process, thereby affecting the The cutting process of the second air-permeable sealing part 14 is easy to form a burr at the joint of the second air-permeable sealing part 14 and the end surface of the second end 112 during the cutting process of the second air-permeable sealing part 14 .

Please refer to FIGS. 25 and 26 , FIG. 25 is a schematic structural diagram of the HNB cartridge provided by an embodiment of the application; FIG. 26 is an exploded perspective view of the HNB cartridge provided by the embodiment of FIG. 25 . The HNB pod 1 includes a tube body 20, a sealing member 30, a smoking member 40, a filter member 50 and the cooling assembly 10 as described above. The tube body 20 has an accommodating space 21 . The sealing member 30 is sealed at one end of the tube body 20 . The smoking member 40 is disposed in the accommodating space 21 and adjacent to the sealing member 30 . The cooling assembly 10 is disposed in the accommodating space 21 , at the end of the smoking member 40 away from the sealing member 30 , and the first air-permeable sealing portion 12 is adjacent to the cooling portion 13 compared to the cooling portion 13 . Smoking member 40 . The filter element 50 is disposed in the accommodating space 21 and disposed on the side of the cooling assembly 10 away from the smoking element 40 .

In this embodiment, the smoking member 40 is equipped with an aerosol-generating substrate, so the smoking member 40 will generate a high-temperature aerosol when heated. The HNB pod 1 is sucked through the filter element 50 , so that the aerosol passes through the cooling element 10 and the filter element 50 in sequence from the smoking element 40 . After the aerosol flows through the cooling component 10 , the temperature will decrease to a suitable suction temperature, so that the aerosol has a suitable suction temperature after flowing out from the filter element 50 .

Although the embodiments of the present application have been shown and described above, it should be understood that the above embodiments are exemplary and should not be construed as limitations to the present application. Changes, modifications, substitutions, and alterations are made to the embodiments, and these improvements and modifications are also considered as the protection scope of the present application.

Claims (10)

1. A preparation method of a cooling assembly, wherein the preparation method of the cooling assembly comprises: Provide a plurality of cooling pipes, the cooling pipes include a first end and a second end arranged opposite to each other, and the cooling pipes have a receiving space; Put the first end into the accommodating space in the glue accumulator, and contact with the binder in the accommodating space, so that the end faces of the first ends of the plurality of cooling pipes are flush and adhered with adhesive; providing a first air-permeable seal, and attaching the end face of the first end adhering with the adhesive to the first air-permeable seal; cutting the first breathable seal to form a first breathable seal portion that seals the end face of the first end; and The cooling part is filled into the accommodating space of the cooling pipe from the second end. 2 . The method for preparing a cooling assembly according to claim 1 , wherein the method for preparing the cooling assembly is performed after “filling the cooling portion into the accommodation space of the cooling pipe from the second end”. 3 . Also includes: Turn over the glue accumulator; Put the second end into the accommodating space in the glue accumulator, and contact with the adhesive in the accommodating space, so that the end faces of the second ends of the plurality of cooling pipes are flat aligned and adhered with adhesive; providing a second breathable seal, abutting the end face of the adhesive-adhered second end with the second breathable seal; and The second gas permeable seal is cut to form a second gas permeable sealing portion that seals the end face of the second end. 3. The method for preparing a cooling assembly according to claim 1 or 2, characterized in that, in the "providing a plurality of cooling pipes, the cooling pipes include a first end and a second end arranged opposite to each other. After the cooling pipe has an accommodating space", after the "Put the first end into the accommodating space in the glue accumulator, and contact the adhesive in the accommodating space, so that the plurality of Before the end face of the first end of the cooling pipe is flush and adhered with an adhesive, the preparation method of the cooling assembly further includes: Scrape off the adhesive that exceeds the first preset height in the glue storage member, and the range of the first preset height h1 is: 0.1mm≤h1≤0.3mm. 4. The method for preparing a cooling assembly according to claim 1, wherein the "putting the first end into the accommodating space in the glue accumulating member, and connecting it with the adhesive in the accommodating space. The adhesive contacting, so that the end faces of the first ends of the plurality of cooling pipes are flush and adhered with the adhesive" comprising: Disposing the glue accumulating member on one side of the first end and spaced apart from the first end; Push the cooling tube from the second end to the first end, and the pushing force F is: 1N≤F≤1.5N; and Dip the end face of the first end into the adhesive in the accommodating space until the end face of the first end abuts the glue accumulating member, so that the first end is adjacent to the first end. A portion of the end face is adhered with an adhesive. 5. The method for preparing a cooling assembly according to claim 1 or 2, characterized in that, in the "providing a first breathable seal, the end face of the first end adhering with the adhesive is connected to the After the first air-permeable seal is attached”, and before the “cutting the first air-permeable seal to form a first air-permeable sealing portion for sealing the first end”, the preparation method of the cooling assembly further includes: : A first vent hole is formed by cutting the area surrounded by the part of the first ventilating seal and the end face of the first end that is in contact with the first end. 6. The method for preparing a cooling assembly according to claim 5, wherein the "cutting the area surrounded by the part of the first air-permeable seal and the end face of the first end that abuts on to form the first air-permeable seal". A "vent" includes: selecting a predetermined area within the area surrounded by the portion of the first gas permeable seal that is in contact with the end face of the first end; and The outer contour of the preset area is cut to form first ventilation holes. 7. The method for preparing a cooling assembly according to claim 5, wherein the "cutting the area surrounded by the part of the first air-permeable seal and the end face of the first end that is in contact with the end face of the first end to form a A "vent" includes: selecting a predetermined area within the area surrounded by the portion of the first gas permeable seal that is in contact with the end face of the first end; and The inside of the preset area is cut to form the first ventilation hole. 8. a preparation method of heat-not-burn smoke bomb, is characterized in that, the preparation method of described heat-not-burn smoke bomb comprises: a pipe body is provided, the pipe body has an accommodating space; sealing one end of the tubular body with a seal; inserting the smoking element into the accommodating space from the end facing away from the sealing element, and making the smoking element adjacent to the sealing element; The cooling assembly prepared by the method for preparing a cooling assembly according to any one of claims 1-7 is loaded into the accommodating space from one end away from the seal, and the first end is opposite to the second an end disposed adjacent to the smoking member; and The filter element is installed into the accommodating space from the end facing away from the sealing element. 9. A cooling assembly, wherein the cooling assembly comprises: a cooling pipe, the cooling pipe includes a first end and a second end arranged opposite to each other, and the cooling pipe has a receiving space; and a cooling part, the cooling part is accommodated in the accommodating space, and the range of the volume ratio a of the cooling part to the accommodating space is: 20%≦a≦60%; The cooling assembly further includes a first adhesive layer and a first air-permeable sealing portion; and/or, the cooling assembly further includes a second adhesive layer and a second air-permeable sealing portion; When the cooling component includes a first adhesive layer and a first air-permeable sealing part: the first adhesive layer is disposed on the end face of the first end and is located on the end face of the first end adjacent to the first end part, the first air-permeable sealing part is bonded to the end face of the first end through the first adhesive layer; When the cooling component includes a second adhesive layer and a second air-permeable sealing portion: the second adhesive layer is disposed on the end face of the second end and is located at the portion of the second end adjacent to the end face of the second end , the second air-permeable sealing part is bonded to the end face of the second end through the second adhesive layer. 10. A heat-not-burn smoke bomb, characterized in that the heat-not-burn smoke bomb comprises: a pipe body, the pipe body has an accommodating space; a sealing member, the sealing member is sealed at one end of the first pipe body; a smoking member, the smoking member is disposed in the accommodating space and is disposed adjacent to the sealing member; The cooling assembly according to claim 9, wherein the cooling assembly is disposed in the accommodating space, at an end of the smoking member away from the sealing member, and the first air-permeable sealing portion is cooler than the first air-permeable sealing portion part adjacent to the smoking member; and The filter element is arranged in the accommodating space and is arranged on the side of the cooling component away from the smoking element.

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