Storage bottle and storage device
By using a double-layered storage bottle design, with an inner bottle and an outer bottle forming a sandwich, the outer bottle provides light protection while the inner bottle provides cushioning, and the sealing element provides a seal, the problem of moisture and volatilization prevention in the storage of atomized matrix is solved, achieving stable storage and improved safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HG INNOVATION LTD
- Filing Date
- 2025-04-23
- Publication Date
- 2026-07-14
Smart Images

Figure CN224492203U_ABST
Abstract
Description
Technical Field
[0001] This application belongs to the field of electronic atomization technology, specifically relating to a storage bottle and storage device for an atomization matrix. Background Technology
[0002] With the development of atomizing devices, diversified atomizing devices are becoming increasingly popular. Currently, to supply e-liquid to atomizing devices with various flavors, different atomizing bases are used, and these bases need to be stored in storage devices for long-term preservation. However, because atomizing bases are volatile, the storage devices need to be moisture-proof and evaporation-proof, but current storage devices cannot achieve these effects, thus affecting the storage performance of the atomizing base. Utility Model Content
[0003] The purpose of this application is to provide a storage bottle and storage device for an atomizing matrix, which at least solves the problem that storage bottles in traditional technologies are difficult to prevent moisture and volatilization.
[0004] This application embodiment provides a storage bottle for storing an atomizing matrix, the storage bottle comprising:
[0005] A bottle assembly includes an inner bottle and an outer bottle spaced apart. The inner bottle is disposed inside the outer bottle and forms a sandwich between them. One end of the outer bottle has a bottle opening. The inner bottle encloses and forms a storage cavity. The storage cavity is open on one side of the bottle opening. The outer bottle has at least a light-shielding structure.
[0006] Bottle cap, wherein the bottle cap is detachably connected to the bottle opening;
[0007] A sealing element, which is a hollow annular shape, is provided for sealing the bottle opening, and the inner annular surface of the sealing element is configured to fit against the outer peripheral surface of the inner bottle body into the storage cavity.
[0008] In some embodiments, the interlayer between the inner bottle and the outer bottle is filled with a cushioning structure.
[0009] In some embodiments, the outer bottle has a connecting wall near the bottle opening, the connecting wall extending toward the axis of the bottle body, the connecting wall and the interlayer defining a buffer cavity, the buffer structure being located within the buffer cavity, and the sealing element being disposed on the side of the connecting wall facing the bottle opening.
[0010] In some embodiments, the buffer structure is a flexible buffer, wherein the seal is filled with an absorbent structure.
[0011] In some embodiments, the buffer structure is an elastic bending structure;
[0012] The elastic bending structure includes at least two connected bending portions, one end of which abuts against the inner wall of the outer bottle and the other end of which abuts against the outer wall of the inner bottle, and the at least two connected bending portions are arranged around the circumference of the inner bottle.
[0013] In some embodiments, an adhesive layer is provided between the buffer structure and the outer bottle, so that in the event of breakage of the outer bottle, the broken pieces of the outer bottle can adhere to the adhesive layer.
[0014] In some embodiments, the outer bottle is a light-shielding material, and the outer bottle having the light-shielding material constitutes the light-shielding structure;
[0015] And / or, a light-blocking net is provided on the outside of the outer bottle, the light-blocking net is sleeved on the outside of the outer bottle, and the light-blocking net constitutes the light-blocking structure.
[0016] In some embodiments, this application also provides a storage device for an atomizing matrix, the storage device for the atomizing matrix including an inner bottle and a storage bottle as described in any of the above embodiments;
[0017] At least a portion of the inner bottle can be accommodated in the storage cavity. The inner bottle includes a stopper and a storage cylinder. The storage cylinder is a single-end open cylinder structure. The stopper is connected to the opening of the storage cylinder to form a accommodating cavity. The atomizing matrix can be stored in the accommodating cavity. The outer circumferential surface of the storage cylinder and the inner circumferential surface of the seal are interference-fitted. The bottom surface of the stopper and the top surface of the seal are in contact.
[0018] In some embodiments, the end of the stopper away from the storage cylinder includes a limiting protrusion that abuts against the end face of the seal facing the bottle opening.
[0019] In some embodiments, the bottle stopper is provided with a liquid outlet tube, one end of which is connected to the receiving cavity, and the other end of which extends outward and is disposed on the end face of the bottle stopper away from the receiving cavity.
[0020] In this embodiment, the bottle assembly includes an inner bottle and an outer bottle spaced apart. The inner bottle is located inside the outer bottle, forming a sandwich between them. One end of the outer bottle has a bottle opening. The inner bottle encloses and forms a storage cavity, which is open on the bottle opening side. Therefore, the sandwich formed by the inner and outer bottles can reduce the temperature change in the storage cavity within the inner bottle, thereby reducing the volatilization of the atomizing matrix in the storage cavity. The outer bottle has at least a partial light-shielding structure, which reduces the amount of external light entering the inner bottle, reducing the contact between the inner bottle and the outside, lowering the temperature change in the storage cavity within the inner bottle, and further reducing the volatilization of the atomizing matrix in the storage cavity. Furthermore, due to its hollow annular shape, the seal is located at the bottle opening, and the inner annular surface of the seal is configured to fit against the outer circumferential surface of the inner bottle body inserted into the storage cavity. Therefore, after the inner bottle body is inserted into the storage cavity, the inner annular surface of the seal and the outer circumferential surface of the inner bottle body fit together, thereby preventing external moisture from entering the storage cavity through the bottle opening and effectively sealing and absorbing water at the bottle opening, thus achieving a moisture-proof effect. In summary, when storing atomizing matrix using the storage bottle body provided in this application embodiment, it can achieve moisture-proof and anti-evaporation functions. Attached Figure Description
[0021] To more clearly illustrate the technical solutions in the embodiments of this application or related technologies, the drawings used in the description of the embodiments or related technologies will be briefly introduced below. Obviously, the drawings described below are some embodiments of this disclosure. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0022] Figure 1 This is a schematic diagram of one of the structures of a storage bottle provided in an embodiment of this application;
[0023] Figure 2 This is one of the internal structural diagrams of a storage bottle provided in an embodiment of this application;
[0024] Figure 3 This is a second schematic diagram illustrating the structure of another storage bottle provided in an embodiment of this application;
[0025] Figure 4 This is a second schematic diagram showing the internal structure of another storage bottle provided in an embodiment of this application;
[0026] Figure 5 This is a schematic diagram of the structure of an inner bottle provided in an embodiment of this application;
[0027] Figure 6 This is a schematic diagram of one of the structures of a storage device for an atomizing matrix provided in an embodiment of this application;
[0028] Figure 7This is a second schematic diagram illustrating the structure of a storage device for an atomizing matrix provided in an embodiment of this application.
[0029] Figure 8 This is the third schematic diagram illustrating the structure of a storage device for an atomizing matrix provided in an embodiment of this application.
[0030] Figure 9 This is the fourth schematic diagram showing the structure of a storage device for an atomizing matrix provided in an embodiment of this application.
[0031] Figure label:
[0032] 1: Storage bottle body; 11: Inner bottle; 12: Outer bottle; 121: Connecting wall; 13: Storage cavity; 14: Bottle cap; 15: Sealing element; 16: Buffer structure; 161: Flexible buffer element; 162: Elastic bending structure; 17: Adhesive layer; 18: Light-shielding net; 101: Buffer cavity;
[0033] 2: Inner bottle body; 21: Bottle stopper; 211: Liquid outlet pipe; 212: Limiting protrusion ring; 22: Storage cylinder; 23: Receiving cavity. Detailed Implementation
[0034] The present application will now be described in further detail with reference to the accompanying drawings and specific embodiments. Similar elements in different embodiments are referred to by related similar element reference numerals. In the following embodiments, many details are described to facilitate a better understanding of the present application. However, those skilled in the art will readily recognize that some features may be omitted in different situations, or may be replaced by other elements, materials, or methods. In some cases, certain operations related to the present application are not shown or described in the specification. This is to avoid obscuring the core parts of the present application with excessive description. For those skilled in the art, detailed description of these related operations is not necessary; they can fully understand the related operations based on the description in the specification and general technical knowledge in the art.
[0035] Furthermore, the features, operations, or characteristics described in the specification can be combined in any suitable manner to form various embodiments. At the same time, the steps or actions in the method description can be rearranged or adjusted in a manner obvious to those skilled in the art. Therefore, the various orders in the specification and drawings are only for the clear description of a particular embodiment and do not imply a necessary order, unless otherwise stated that a particular order must be followed.
[0036] The serial numbers assigned to components in this document, such as "first" and "second," are used only to distinguish the described objects and have no sequential or technical meaning. The terms "connection" and "linkage" used in this application, unless otherwise specified, include both direct and indirect connections (linkages).
[0037] In related technologies, there is a problem that the storage bottle 1 is difficult to prevent moisture and volatilization.
[0038] In this application, an improved structure of the storage bottle 1 is adopted to solve the above-mentioned problems.
[0039] Please see Figures 1 to 5 As shown, this application provides a storage bottle 1, which includes:
[0040] The bottle assembly includes an inner bottle 11 and an outer bottle 12 spaced apart. The inner bottle 11 is located inside the outer bottle 12 and forms a sandwich between them. One end of the outer bottle 12 has a bottle opening. The inner bottle 11 encloses and forms a storage cavity 13. The storage cavity 13 is open on one side of the bottle opening. The outer bottle 12 has at least a light-shielding structure.
[0041] Bottle cap 14, bottle cap 14 is detachably connected to the bottle opening;
[0042] The sealing element 15 is a hollow ring, which is sealed at the bottle mouth, and the inner ring surface of the sealing element 15 is configured to fit against the outer peripheral surface of the inner bottle 2 that is inserted into the storage cavity 13.
[0043] As can be seen from the above embodiments, in this application embodiment, since the bottle assembly includes an inner bottle 11 and an outer bottle 12 spaced apart, the inner bottle 11 is disposed inside the outer bottle 12 and forms a sandwich between them. One end of the outer bottle 12 has a bottle opening, and the inner bottle 11 surrounds and forms a storage cavity 13, which is open on the bottle opening side. Therefore, the sandwich formed by the inner bottle 11 and the outer bottle 12 can reduce the temperature change of the storage cavity 13 in the inner bottle 11, thereby reducing the volatilization of the atomizing matrix in the storage cavity 13. The outer bottle 12 has at least a partial light-shielding structure, so the light-shielding structure of the outer bottle 12 can reduce the amount of external light entering the inner bottle 11, reduce the contact between the inner bottle 11 and the outside, reduce the temperature change of the storage cavity 13 in the inner bottle 11, and thus reduce the volatilization of the atomizing matrix in the storage cavity 13. Furthermore, due to its hollow annular shape, the seal is located at the bottle opening, and the inner annular surface of the seal 15 is configured to fit against the outer circumferential surface of the inner bottle 2 inserted into the storage cavity 13. Therefore, after the inner bottle 2 is inserted into the storage cavity 13, the inner annular surface of the seal 15 fits against the outer circumferential surface of the inner bottle 2, thereby preventing external moisture from entering the storage cavity 13 through the bottle opening and effectively sealing and absorbing water at the bottle opening, thus achieving a moisture-proof effect. In summary, when storing the atomizing matrix using the storage bottle 1 provided in this embodiment, it can achieve moisture-proof and anti-evaporation effects.
[0044] In the above embodiments, the inner bottle 11 and the outer bottle 12 can be cylindrical, prismatic, or other shaped shell structures. The outer bottle 12 is a single-end open shell structure. The inner bottle 11 and outer bottle 12 can be fixedly connected by integral injection molding, adhesive bonding, or other detachable methods, making the storage bottle 1 a double-layer structure. This allows the atomized matrix to be stored in the inner cavity of the inner bottle 11, and the light-shielding structure on the outer bottle 12 provides light protection for the atomized matrix in the inner bottle 11. This light-shielding structure can be a light-shielding material in the outer bottle 12 or other light-shielding structures provided on the outer wall of the outer bottle 12; this application does not limit this.
[0045] The bottle cap 14 and the bottle opening of the outer bottle 12 are detachably connected to facilitate the insertion of the inner bottle body 2 into the inner bottle 11. The bottle cap 14 can be detachably connected to the bottle opening of the outer bottle 12 by means of threaded connection, snap-fit, abutment, etc.
[0046] The sealing element 15 disposed at the bottle opening can be an integral sealing element with flexible cushioning, a split sealing element with flexible cushioning, a sealing structure filled with a water-absorbing structure, or other structures with a sealing effect. This application embodiment does not limit this. The sealing element 15 has a ring-shaped structure to seal the bottle opening in the hollow portion of the sealing element 15, and allows the inner ring surface of the sealing element 15 to fit against the outer circumferential surface of the inner bottle body 2, achieving the sealing effect of the sealing element 15.
[0047] It should be noted that, in this embodiment of the application, the surface of the bottle cap 14 can be a concave curved surface structure, so as to provide the operator with a sufficient force application surface and facilitate the removal of the bottle cap 14.
[0048] In some embodiments, a cushioning structure 16 is filled in the interlayer between the inner bottle 11 and the outer bottle 12.
[0049] In this embodiment, the buffer structure 16 filled in the interlayer between the inner bottle 11 and the outer bottle 12 can provide a certain force buffer for the storage bottle 1, thereby avoiding damage to the storage structure when the storage bottle 1 is dropped. On the one hand, it can extend the service life of the storage bottle 1, and on the other hand, it can ensure that the atomizing matrix has a stable storage environment, so that it will not splash even when the storage bottle 1 is dropped.
[0050] It should be noted that the buffer structure 16 can be an integral flexible structure, or other elastic structures with deformable structures, or other structures that can provide a certain degree of cushioning. In addition, the inner bottle 11 can be an independent and detachable structure relative to the outer bottle 12, thus facilitating the placement of the buffer structure 16 in the interlayer between the outer bottle 12 and the inner bottle 11. The inner bottle 11, the outer bottle 12, and the buffer structure 16 can also be integrally formed, so that the buffer structure 16 is located in the interlayer between the outer bottle 12 and the inner bottle 11.
[0051] In some embodiments, such as Figure 2 and Figure 4 As shown, the outer bottle 12 has a connecting wall 121 near the bottle mouth. The connecting wall 121 extends in a direction close to the axis of the bottle body. The connecting wall 121 and the interlayer define a buffer cavity 101. The buffer structure 16 is located in the buffer cavity 101. The sealing element 15 is disposed on the side of the connecting wall 121 facing the bottle mouth.
[0052] It should be noted that the connecting wall 121 is part of the structure of the outer bottle 12. On the one hand, it facilitates the increase of the integrity between the outer bottle 12 and the inner bottle 11 through the connecting wall 121. On the other hand, it facilitates the sealing of the interlayer between the outer bottle 12 and the inner bottle 11 through the connecting wall 121. In this way, since the outer bottle 12 has the connecting wall 121 near the bottle mouth, and the connecting wall 121 extends in the direction close to the axis of the bottle body, the connecting wall 121 and the interlayer define the buffer cavity 101. The buffer structure 16 is located in the buffer cavity 101, and the sealing element 15 is set on the side of the connecting wall 121 facing the bottle mouth. Therefore, the connecting wall 121 makes the sealing element 15, the outer bottle 12 and the inner bottle 11 form an integral structure, which is beneficial to ensuring the sealing effect of the sealing element 15.
[0053] It should also be noted that, regarding the connection position between the connecting wall 121 and the inner bottle 11, such as... Figure 3 and Figure 4 As shown, in some embodiments, the end of the connecting wall 121 away from the outer bottle 12 can be connected to the opening of the inner bottle 11 facing the bottle mouth, and the sealing member 15 is connected to the surface of the connecting wall 121 facing the bottle mouth. Figure 1 and Figure 2 As shown, in some embodiments, the end of the connecting wall 121 away from the outer bottle 12 can be connected to the outside of the inner bottle 11. The opening of the inner bottle 11 and the end face of the seal 15 away from the connecting arm are flush, so that the seal 15 is connected in the interlayer formed by the connecting wall 121, the outer bottle 12, and the inner bottle 11. In addition, the seal 15 may include a water-absorbing structure, which can absorb moisture entering the storage cavity 13 from the outside, thereby further improving the moisture-proof performance of the storage device. It should be noted that the water-absorbing structure can usually be a structure that is not easy to shape, such as a water-absorbing sponge, water-absorbing silicone, or highly absorbent resin. Therefore, the water-absorbing structure can be positioned and shaped by the cavity formed by the connecting wall 121, the outer bottle 12, and the inner bottle 11, ensuring the stability of the water-absorbing structure installation, facilitating the installation of the water-absorbing structure, and ensuring the water absorption effect of the water-absorbing structure.
[0054] For buffer structure 16, such as Figure 6 , Figure 7 and Figure 8 As shown, in one possible implementation, the buffer structure 16 is a flexible buffer 161, and the seal 15 is filled with a flexible absorbent structure.
[0055] In this embodiment, since the buffer structure 16 is a flexible buffer element 161, it can fill the buffer cavity 101 formed between the connecting wall 121, the outer bottle 12, and the inner bottle 11. This allows the buffer structure 16 to not only provide a certain buffering effect, preventing damage to the storage bottle 1 when it falls, but also, since the sealing element 15 is filled with a flexible water-absorbing structure, it can absorb moisture inside the storage bottle under the combined action of the buffer structure 16 and the sealing element 15, further improving the moisture-proof performance of the storage bottle 1.
[0056] For buffer structure 16, in another possible implementation, such as Figure 9 As shown, the buffer structure 16 is an elastic bending structure 162. The elastic bending structure 162 includes at least two connected bending parts. One end of the bending part abuts against the inner wall of the outer bottle 12, and the other end of the bending part abuts against the outer wall of the inner bottle 11. At least two connected bending parts are arranged around the circumference of the inner bottle 11.
[0057] In this embodiment, the bends in the elastic bending structure 162 provide it with elasticity and a buffering force. Thus, when the outer bottle 12 is impacted by a drop, the two connected bends in the elastic bending structure 162 deform upon reaching them, absorbing the impact and preventing damage to the outer bottle 12 structure. This further protects the integrity of the inner bottle 11 structure.
[0058] It should be noted that the elastic bending structure 162 needs to be wrapped around the periphery of the inner bottle 11, so that any position on the periphery of the inner bottle 11 is protected by the bending portion included in the elastic bending structure 162. Simultaneously, with one end of the bending portion pressing against the inner wall of the outer bottle 12 and the other end pressing against the outer wall of the inner bottle 11, the outer bottle 12 can immediately transfer the impact force to the bending portion for absorption upon being subjected to impact. It should also be noted that the elastic bending structure 162 can be a helical elastic structure, such as a spring, or a frame structure including multiple bending arms, such as a bent chain structure, or a cylindrical structure formed by winding a bent tube; this embodiment does not limit this.
[0059] In some embodiments, such as Figure 8 As shown, an adhesive layer 17 is provided between the buffer structure 16 and the outer bottle 12. In the event of breakage of the outer bottle 12, the broken pieces of the outer bottle 12 can adhere to the adhesive layer 17.
[0060] In this embodiment, since an adhesive layer 17 is provided between the buffer structure 16 and the outer bottle 12, even if the outer bottle 12 breaks (the outer bottle 12 becomes multiple fragments after being subjected to force), the broken pieces of the outer bottle 12 can be adhered to the adhesive layer 17, thereby preventing the broken pieces of the outer bottle 12 from splashing down and causing injury to personnel, and further improving the safety performance of the storage bottle 1.
[0061] In one possible implementation of the light-shielding structure, the outer bottle 12 is made of light-shielding material, and the outer bottle 12 with light-shielding material constitutes the light-shielding structure.
[0062] In this embodiment, when the outer bottle 12 is a light-shielding material and the outer bottle 12 with the light-shielding material constitutes a light-shielding structure, the light-shielding material of the outer bottle 12 can effectively absorb or reflect external light, thereby achieving the light-shielding effect. Moreover, this embodiment does not require the addition of other structures to the outer bottle 12, and the entire structure is relatively simple and easy to process and manufacture.
[0063] For light-shielding structures, another possible implementation method is as follows: Figure 6 and Figure 7As shown, a light-blocking net 18 is provided on the outside of the outer bottle 12. The light-blocking net 18 is fitted over the outside of the outer bottle 12, and the light-blocking net 18 constitutes a light-blocking structure.
[0064] In this embodiment, a light-shielding net 18 is provided on the outside of the outer bottle 12. The light-shielding net 18 is fitted over the outside of the outer bottle 12, forming a light-shielding structure. This reduces the amount of external light entering the interior of the outer bottle 12, thus achieving the same light-shielding effect. Furthermore, this embodiment can increase the surface roughness of the outer bottle 12 through the light-shielding net 18. This further prevents the storage bottle 1 from slipping and falling when the operator is holding it.
[0065] As can be seen from the above embodiments, in this application embodiment, since the bottle assembly includes an inner bottle 11 and an outer bottle 12 spaced apart, the inner bottle 11 is disposed inside the outer bottle 12 and forms a sandwich between them. One end of the outer bottle 12 has a bottle opening, and the inner bottle 11 surrounds and forms a storage cavity 13, which is open on the bottle opening side. Therefore, the sandwich formed by the inner bottle 11 and the outer bottle 12 can reduce the temperature change of the storage cavity 13 in the inner bottle 11, thereby reducing the volatilization of the atomizing matrix in the storage cavity 13. The outer bottle 12 has at least a partial light-shielding structure, so the light-shielding structure of the outer bottle 12 can reduce the amount of external light entering the inner bottle 11, reduce the contact between the inner bottle 11 and the outside, reduce the temperature change of the storage cavity 13 in the inner bottle 11, and thus reduce the volatilization of the atomizing matrix in the storage cavity 13. Furthermore, due to its hollow annular shape, the seal is located at the bottle opening, and the inner annular surface of the seal 15 is configured to fit against the outer circumferential surface of the inner bottle 2 inserted into the storage cavity 13. Therefore, after the inner bottle 2 is inserted into the storage cavity 13, the inner annular surface of the seal 15 fits against the outer circumferential surface of the inner bottle 2, thereby preventing external moisture from entering the storage cavity 13 through the bottle opening and effectively sealing and absorbing water at the bottle opening, thus achieving a moisture-proof effect. In summary, when storing the atomizing matrix using the storage bottle 1 provided in this embodiment, it can achieve moisture-proof and anti-evaporation effects.
[0066] In other embodiments, such as Figures 6 to 9 As shown, this application embodiment also provides a storage device for atomizing matrix. The storage device for atomizing matrix includes an inner bottle 2 and a storage bottle 1 as described in any of the above embodiments. At least a portion of the inner bottle 2 can be accommodated in a storage cavity 13. The inner bottle 2 includes a stopper 21 and a storage cylinder 22. The storage cylinder 22 is a single-end open cylinder structure. The stopper 21 is connected to the opening of the storage cylinder 22 to form a receiving cavity 23. The atomizing matrix can be stored in the receiving cavity 23. The outer peripheral surface of the storage cylinder 22 and the inner ring surface of the sealing member 15 are interference-fitted. The bottom surface of the stopper and the top surface of the sealing member 15 are in contact.
[0067] In this embodiment, since the inner bottle 2 includes a stopper 21 and a storage cylinder 22, and the storage cylinder 22 is a single-end open cylinder structure, the stopper 21 is connected to the opening of the storage cylinder 22 to form a receiving cavity 23, the atomizing matrix can be stored in the receiving cavity 23. The outer peripheral surface of the storage cylinder 22 and the inner ring of the sealing member 15 are interference-fitted, and the bottom surface of the stopper and the top surface of the sealing member 15 are in contact. Therefore, the atomizing matrix can be stored in the receiving cavity 23 of the inner bottle 2 first, and then the inner bottle 2 can be placed entirely in the storage bottle 1. In this way, not only can the light-shielding structure of the outer bottle 12 reduce the amount of external light entering the receiving cavity 23, reducing the contact between the receiving cavity 23 and the outside, but also reducing the temperature change of the receiving cavity 23, thereby reducing the volatilization of the atomizing matrix in the receiving cavity 23. The outer circumferential surface of the storage cylinder 22 and the inner ring surface of the seal 15 are interference-fitted, and the bottom surface of the bottle stopper and the top surface of the seal 15 are in contact. This can prevent moisture and reduce the evaporation of liquid in the inner bottle 2. Moreover, the seal 15 can prevent external moisture from entering the storage cavity 13 through the gap at the connection between the bottle stopper 21 and the storage cylinder 22.
[0068] In some embodiments, the end of the stopper 21 away from the storage cylinder 22 includes a limiting protrusion 212, which abuts against the end face of the seal 15 facing the bottle opening.
[0069] In this embodiment, the end of the bottle stopper 21 furthest from the storage cylinder 22 includes a limiting protrusion 212, which abuts against the end face of the sealing member 15 facing the bottle opening. Therefore, the limiting protrusion 212 ensures the fixation of the inner bottle 2, maintaining its positional stability. Furthermore, the limiting protrusion 212 prevents moisture from entering the receiving cavity 23 through the gap at the connection between the bottle stopper 21 and the storage cylinder 22, further ensuring the sealing effect of the sealing member 15 and playing a role in moisture prevention and reducing liquid evaporation from the inner bottle 2.
[0070] In some embodiments, the bottle stopper 21 is provided with a liquid outlet tube 211, one end of which is connected to the receiving cavity 23, and the other end of which extends out and protrudes from the end face of the bottle stopper 21 away from the receiving cavity 23.
[0071] In this embodiment, when taking liquid, the inner bottle 2 can be taken out first, and then the storage cylinder 22 can be squeezed to make the pressure inside the storage cylinder 22 greater than the pressure outside, so that the atomized matrix can flow out from the receiving cavity 23 along the liquid outlet pipe 211, which facilitates the removal of the atomized matrix. At the same time, the atomized matrix will not be leaked during the entire process of removing the atomized matrix.
[0072] The various embodiments in the specification are described in a progressive manner, with each embodiment focusing on the differences from other embodiments. The same or similar parts between the various embodiments can be referred to each other.
[0073] Although preferred embodiments of the present application have been described, those skilled in the art, upon learning the basic inventive concept, can make other changes and modifications to these embodiments. Therefore, the appended claims are intended to be interpreted as including the preferred embodiments as well as all changes and modifications falling within the scope of the embodiments of the present application.
[0074] Finally, it should be noted that in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or terminal device that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or terminal device. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or terminal device that includes said element.
[0075] The present application has been described in detail above. Specific examples have been used to illustrate the principles and implementation methods of the present application. The description of the above embodiments is only for the purpose of helping to understand the method and core ideas of the present application. At the same time, for those skilled in the art, there will be changes in the specific implementation methods and application scope based on the ideas of the present application. Therefore, the content of this specification should not be construed as a limitation of the present application.
Claims
1. A storage bottle for storing an atomizing matrix, characterized in that, The storage bottle includes: A bottle assembly includes an inner bottle and an outer bottle spaced apart. The inner bottle is disposed inside the outer bottle and forms a sandwich between them. One end of the outer bottle has a bottle opening. The inner bottle encloses and forms a storage cavity. The storage cavity is open on one side of the bottle opening. The outer bottle has at least a light-shielding structure. Bottle cap, wherein the bottle cap is detachably connected to the bottle opening; A sealing element, which is a hollow annular shape, is provided for sealing the bottle opening, and the inner annular surface of the sealing element is configured to fit against the outer peripheral surface of the inner bottle body into the storage cavity.
2. The storage bottle according to claim 1, characterized in that, The interlayer between the inner bottle and the outer bottle is filled with a cushioning structure.
3. The storage bottle according to claim 2, characterized in that, The outer bottle has a connecting wall near the bottle opening, the connecting wall extends in a direction close to the axis of the bottle body, the connecting wall and the interlayer define a buffer cavity, the buffer structure is located in the buffer cavity, and the sealing element is disposed on the side of the connecting wall facing the bottle opening.
4. The storage bottle according to claim 2, characterized in that, The buffer structure is a flexible buffer element, and the sealing element is filled with a water-absorbing structure.
5. The storage bottle according to claim 2, characterized in that, The buffer structure is an elastic bending structure; The elastic bending structure includes at least two connected bending portions, one end of which abuts against the inner wall of the outer bottle and the other end of which abuts against the outer wall of the inner bottle, and the at least two connected bending portions are arranged around the circumference of the inner bottle.
6. The storage bottle according to claim 4, characterized in that, An adhesive layer is provided between the buffer structure and the outer bottle, so that in the event of breakage of the outer bottle, the broken pieces of the outer bottle can adhere to the adhesive layer.
7. The storage bottle according to any one of claims 1 to 6, characterized in that, The outer bottle is made of light-shielding material, and the outer bottle with light-shielding material constitutes the light-shielding structure. And / or, a light-blocking net is provided on the outside of the outer bottle, the light-blocking net is sleeved on the outside of the outer bottle, and the light-blocking net constitutes the light-blocking structure.
8. A storage device for storing an atomizing matrix, characterized in that, The storage device includes an inner bottle and a storage bottle according to any one of claims 1 to 7; At least a portion of the inner bottle can be accommodated in the storage cavity. The inner bottle includes a stopper and a storage cylinder. The storage cylinder is a single-end open cylinder structure. The stopper is connected to the opening of the storage cylinder to form a accommodating cavity. The atomizing matrix can be stored in the accommodating cavity. The outer circumferential surface of the storage cylinder and the inner circumferential surface of the seal are interference-fitted. The bottom surface of the stopper and the top surface of the seal are in contact.
9. The storage device according to claim 8, characterized in that, The end of the stopper away from the storage cylinder includes a limiting protrusion ring, which abuts against the end face of the seal facing the bottle opening.
10. The storage device according to claim 8, characterized in that, The bottle stopper is provided with a liquid outlet tube. One end of the liquid outlet tube is connected to the receiving cavity, and the other end of the liquid outlet tube extends out and protrudes from the end face of the bottle stopper away from the receiving cavity.