Odor releasing device

By designing an odor release device with multiple raw material silo components and control units, the problems of single odor and limited application scenarios in existing technologies have been solved. This enables personalized odor adjustment and multi-scenario adaptation, improving user experience and the wide applicability of the device.

CN224387819UActive Publication Date: 2026-06-23BEIJING ZHIDA HUITONG TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BEIJING ZHIDA HUITONG TECH CO LTD
Filing Date
2025-04-22
Publication Date
2026-06-23

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  • Figure CN224387819U_ABST
    Figure CN224387819U_ABST
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Abstract

The utility model provides a kind of smell release equipment, including multiple raw material bin assemblies, raw material bin assembly includes raw material bin, each raw material bin is used to hold one raw material, the raw material in any two raw material bins is same or different;Control unit, control unit is connected with multiple raw material bins communication, to control the raw material in each raw material bin whether release, and the release amount of the raw material in each raw material bin;Solved the application scene limitation in the prior art, smell single and cannot play a role in multiple fields problem.
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Description

Technical Field

[0001] This utility model relates to the field of terminal technology, and more specifically, to an odor-releasing device. Background Technology

[0002] In the realm of information transmission and sensory experience, humans perceive and understand their environment through sight, hearing, touch, and smell. While electronic devices have become adept at simulating and transmitting visual, auditory, and tactile information with technological advancements, the digitization and intelligentization of olfactory experiences have remained largely unresolved. Currently, automatic perfume spraying devices on the market are primarily used for air purification in large public spaces or for scent dissemination in enclosed areas such as cars. Their main function is to mask odors or provide a single fragrance experience.

[0003] In existing technologies, the design of automatic perfume spraying devices mainly revolves around optimizing the spray mechanism, such as improving spray uniformity and control precision, or enhancing device reliability. Furthermore, existing devices cannot dynamically adjust and generate specific scents based on specific scenarios or user needs to provide a personalized scent experience. The application scenarios of existing technologies are limited, preventing them from playing a role in multiple fields such as smart homes, entertainment, and education, thus limiting the potential of scent as a medium for information transmission. Utility Model Content

[0004] The main objective of this invention is to provide an odor-releasing device to solve the problems of limited application scenarios, single odor, and inability to function in multiple fields in the prior art.

[0005] To achieve the above objectives, according to one aspect of the present invention, an odor release device is provided, comprising a plurality of raw material silo assemblies, each raw material silo comprising a raw material silo, each raw material silo being used to hold a raw material, and the raw materials in any two raw material silos being the same or different;

[0006] The control unit communicates with multiple raw material bins to control whether the raw materials in each bin are released and the amount of raw materials released from each bin.

[0007] Furthermore, the raw material silo assembly also includes an outlet component and an atomizing component; at least a portion of the outlet component is located inside the raw material silo so that the raw material inside the raw material silo is directed to the outlet component; the atomizing component is connected to the outlet component to atomize the raw material on the outlet component to form the original odor; the atomizing component is provided with an odor outlet for the original odor in the atomized state to flow out.

[0008] The odor release device also includes a housing, which includes an odor mixing chamber; the odor outlets of multiple atomizing elements are all connected to the odor mixing chamber, so that the original odors flowing from the odor outlets of at least two of the multiple atomizing elements are mixed in the odor mixing chamber.

[0009] Furthermore, the raw material warehouse includes:

[0010] The hopper body has a feed inlet, and the bottom of the hopper body is detachably connected to the fourth side wall of the box.

[0011] The cover is used in conjunction with the hopper body to open or close the feed inlet. The cover is equipped with a release port.

[0012] The lead-out component is located inside the silo body.

[0013] Furthermore, the raw material hopper assembly also includes an output pipe, the inlet end of which extends into the raw material hopper; the atomizing element is connected to the outlet end of the output pipe;

[0014] The output pipe can be switched on and off, and the on / off state of the output pipe can be controlled by the control unit to control whether the raw materials in the raw material silo are transported from the inlet end to the outlet end.

[0015] Furthermore, the raw material hopper assembly also includes an output pipe, the inlet end of which extends into the raw material hopper; the atomizing element is connected to the outlet end of the output pipe;

[0016] The output pipe can be switched on and off, and the on / off state of the output pipe can be controlled by the control unit to control whether the raw materials in the raw material silo are transported from the inlet end to the outlet end.

[0017] Furthermore, the atomizing element includes a vibrating plate, at least a portion of which is vibratingly configured, and the vibrating plate is connected to a control unit to control the amount of raw material released from each raw material chamber by controlling the vibration time of the vibrating plate.

[0018] Furthermore, the control unit includes multiple control units, each corresponding to a different raw material silo component.

[0019] Furthermore, the odor-releasing device also includes:

[0020] Multiple material channels are set inside the box, and each material channel corresponds to a material hopper component, so that the material hopper components can be installed inside the box through the material channels.

[0021] Furthermore, the multiple material channels include multiple rows of material channel units distributed along a first direction, and each material channel unit includes multiple material channels distributed along a second direction, wherein the first direction is perpendicular to the second direction.

[0022] Furthermore, there are multiple boxes, each containing multiple raw material silo components; the multiple boxes are connected.

[0023] Furthermore, the odor-releasing device also includes:

[0024] A first mounting slot, at least partially disposed on the side wall of the odor mixing chamber away from the raw material chamber, is for mounting the control unit; and / or,

[0025] The third installation slot is located on the side wall of the odor mixing chamber near the raw material chamber for installing a vibrating plate.

[0026] Furthermore, the odor release device also includes a lid that works in conjunction with the box body. The lid has multiple vents at positions corresponding to the odor mixing chamber, so that the mixed gas in the odor mixing chamber can escape through the multiple vents.

[0027] Furthermore, the odor-releasing device also includes a conductive part, which is electrically connected to the control unit for electrical connection with the terminal device; and / or, the odor-releasing device can be wirelessly connected to the terminal device.

[0028] Furthermore, the odor-releasing device also includes:

[0029] An adsorption element is installed on the outer wall of the box to connect the odor-releasing device to the smart electronic device.

[0030] By applying the technical solution of this utility model, multiple raw material bins are set up, each of which can hold different raw materials. This provides a variety of basic odors, laying the foundation for subsequent odor synthesis and personalized customization. A single raw material bin can only provide a fixed odor, while multiple raw material bins allow the equipment to release different odor combinations according to different needs and formulas, thereby meeting the diverse needs of users.

[0031] Each raw material compartment is specifically designed to hold a single type of raw material, ensuring the purity and stability of each scent. Allowing some compartments to store the same raw material enables multiple compartments to work together to increase the intensity or persistence of a scent when a large release is needed. The control unit connects to each compartment via communication, precisely controlling the release amount based on preset formulas or real-time user input. The control unit decides whether to release raw materials from each compartment based on demand, effectively saving materials and avoiding unnecessary waste. Furthermore, the control unit not only decides whether to release raw materials but also controls the specific amount released, which is crucial for finely adjusting scent intensity. Combining these technical features, the equipment can create personalized scents by varying the release amounts and combinations of raw materials according to specific user requirements or situations. Attached Figure Description

[0032] The accompanying drawings, which form part of this application, are used to provide a further understanding of the present invention. The illustrative embodiments of the present invention and their descriptions are used to explain the present invention and do not constitute an undue limitation of the present invention. In the drawings:

[0033] Figure 1 A structural diagram of an odor-releasing device according to an embodiment of this application is shown;

[0034] Figure 2 A schematic diagram of the structure of the vent being located on the lid according to an embodiment of this application is shown;

[0035] Figure 3 This invention provides a schematic diagram showing the positional structure of the spray plate according to an embodiment of the present application.

[0036] Figure 4 A schematic diagram of the box body and box lid according to an embodiment of this application is shown;

[0037] Figure 5 This invention provides a schematic diagram illustrating the structure of at least two stacked boxes according to an embodiment of the present application.

[0038] Figure 6 A schematic diagram of the internal structure of at least two stacked boxes according to an embodiment of this application is shown.

[0039] The above figures include the following reference numerals:

[0040] 100. Box body; 101. First side wall; 102. Second side wall; 103. Third side wall; 105. Box lid; 106. Outlet; 200. Raw material bin; 201. Bin body; 202. Outlet component; 300. Control unit; 301. Wire; 400. Atomizing component; 401. Vibrating plate; 500. Material channel; 600. First mounting slot; 700. Second mounting slot; 800. Third mounting slot; 900. Odor mixing chamber; 910. Conductive part. Detailed Implementation

[0041] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. The present invention will now be described in detail with reference to the accompanying drawings and embodiments.

[0042] Example 1

[0043] This application provides an odor release method, including:

[0044] The terminal device can select the type of odor to be released to generate an odor release command, or the terminal device can automatically identify video or image information to generate an odor release command based on the video or image information.

[0045] The terminal device sends an odor release command to the odor release device;

[0046] Receive odor release instructions, which include the final type of odor the user expects to be released;

[0047] Traverse the preset odor database, determine the odor release scheme corresponding to the odor release instruction based on the odor release instruction, the odor release scheme includes an odor formula, the odor formula includes one or more original odors, and the release ratio of each original odor; the release ratio of each original odor can be controlled by controlling the release time of each original odor in the odor formula.

[0048] According to the odor release scheme, the odor release device is controlled to release the odor according to the determined odor release scheme;

[0049] When the odor formulation includes multiple primary odors, the odor release method also includes the release order of the multiple primary odors, wherein the release order is simultaneous release or release in a preset order;

[0050] The steps for determining the odor release scheme corresponding to the odor release instruction based on the odor type include:

[0051] Based on the odor release scheme, determine the original odor type corresponding to the odor release scheme and mark it as the target odor type;

[0052] Based on the scent formulation, control the release time of the target scent type.

[0053] Specifically, during use, the desired scent type must first be selected on the terminal device, such as apple, banana, orange, etc. After the desired scent type is selected, a scent release command is generated. The terminal device sends the generated scent release command to the scent release device. After receiving the scent release command, the scent release device retrieves the preset scent data path and determines the scent release scheme corresponding to the scent release command. The scent release command includes the final scent type to be released, and the scent release scheme includes a scent formula, which includes one or more original scents and the release ratio of each original scent. The release ratio of each original scent is controlled by controlling the release time of each original scent in the scent formula. When the scent formula includes multiple original scents, the scent release method also includes the release order of multiple original scents, because the production of a scent requires the cooperation of multiple original scents. This includes the possibility that multiple original scents may be released simultaneously, or that some of the multiple original scents may be released first, and after a period of time, other scents may be released.

[0054] Alternatively, the terminal device can automatically identify the currently playing video or image information, and then generate an odor release command based on the video or image information.

[0055] The steps for determining the odor release scheme corresponding to the odor release instruction based on the odor type are as follows: Based on the odor release scheme, determine the original odor type corresponding to the odor release scheme in the preset odor database, and mark the original odor type as the target odor type. Then, based on the odor formula, control the release time of the target odor type to obtain the final odor type.

[0056] The odor release method described in this application allows users to freely select from a variety of odors on their terminal devices, including but not limited to apple, banana, and orange scents. This diverse selection meets users' odor needs in different scenarios and enhances the personalization and scene adaptability of the user experience.

[0057] The odor release method of this application can automatically generate odor release instructions based on the odor type selected by the user. These instructions contain precise odor formulation information. The odor formulation is created by mixing one or more original odors in a specific ratio, and the release ratio and release order of each original odor are controlled by the system.

[0058] By precisely controlling the release time of each primary scent, the proportion of scent release is controlled, ensuring the accurate generation of complex scents. For example, when creating an apple scent, the main apple scent is released first, followed by the sour and sweet scents at set time intervals. This control of the time sequence ensures the layering and authenticity of the scent.

[0059] Considering that odor synthesis depends on the diffusion and interaction of different odor molecules in the air, a release time control algorithm was designed to optimize the odor synthesis process. By releasing the primary odor first, allowing sufficient time for diffusion, and then adding secondary odors at the appropriate time, interference between odors can be effectively prevented, achieving the best odor synthesis effect. This method overcomes the difficulty in controlling the odor mixing ratio in traditional static odor release, realizing dynamic adjustment and precise control of odor release.

[0060] The odor release instruction not only includes the odor type, but may also include contextual information related to the odor release, such as the user's geographical location, time, and environmental conditions. This allows the odor release to blend with the user's current actual scene, creating a more immersive experience.

[0061] For example, when a user is watching a movie depicting a tropical rainforest, the system can identify keywords in the scene information (such as "rainforest" and "early morning") and then select a matching scent release scheme—the fresh scent of earth or leaves after a morning rain. This contextualized scent release not only enhances the user's immersion in the virtual world but also brings new interaction methods to fields such as remote communication, online education, and gaming.

[0062] Example 2

[0063] This application embodiment also provides a terminal device, including a selection module, which includes multiple odor options, each odor option corresponding to a final odor type;

[0064] The generation module communicates with the selection module to generate odor release instructions based on the final odor type;

[0065] The signal transmitting module is connected to the generating module to send the odor release command to the odor release device.

[0066] This application embodiment also provides a terminal device, including an identification module, which is used to automatically identify video frames or image information to obtain identification results;

[0067] The analysis module communicates with the recognition module to analyze the recognition results, obtain the final odor type, and generate odor release instructions;

[0068] The judgment module communicates with the analysis module to send an odor release command to the odor release device when it determines that the terminal device is in an authorized state.

[0069] This application embodiment also provides a terminal device, which includes a selection module, a generation module, and a signal transmission module. The selection module includes multiple odor options, each corresponding to a final odor type. In practical applications, when a user is watching a video or television program featuring food, such as seafood or braised pork, the user can open the terminal device, select the odor option corresponding to the seafood or braised pork flavor from the selection module, and click on the odor option. The generation module will generate an odor release command and send the generated odor release command to an odor release device via the signal transmission module. The odor release device will then release the corresponding odor according to the aforementioned odor release scheme.

[0070] Alternatively, the terminal device provided in this application includes an identification module, an analysis module connected to the identification module, and a judgment module connected to the analysis module. When a user is watching a video or television, if the identification module identifies that the content being played in the current video is a mukbang (eating broadcast), such as eating braised pork, the identification module will generate an identification result and send it to the analysis module. After receiving the identification result, the analysis module will find the corresponding ultimate odor type based on the identification result and generate an odor release command. When the judgment terminal device has been authorized by the user, the judgment module will send the odor release command to the odor release device, which will then release the corresponding odor according to the aforementioned odor release scheme.

[0071] The scent option can be selected via a button or a physical button.

[0072] When a user is watching a video or television, if the software being played is authorized by the terminal device provided in this application embodiment, then the user can directly retrieve and release the corresponding ultimate scent from the terminal device while watching a certain video, so as to achieve the function of visual, auditory and olfactory interactive enjoyment, without having to manually select through the selection module.

[0073] Example 3

[0074] When a user watches a video or the content played on TV is related to scenery, such as flowers or plants, the user can also open the terminal device and select the scent option corresponding to the flowers or plants in the selection module if they want to feel like they are there.

[0075] When watching videos related to specific scents (such as mukbang or scenic videos), users can select scent options that match the video scene through a selection module on their device. This selection module allows users to interact with the device intuitively, expressing their scent preferences through simple actions such as clicking buttons.

[0076] For example, when watching a mukbang video of seafood cooking, users can easily select a seafood flavor option. After receiving the user's selection, the generation module generates a corresponding scent release command based on a preset scent database. This command contains precise scent formula information. The signal transmission module then transmits the scent release command to the scent release device via wired or wireless means, initiating the scent release process.

[0077] This intelligent integration of terminal devices and video content creates a completely new immersive experience. Users can not only perceive the video content through sight and hearing, but also further enhance their sensory experience through smell, as if they were actually in the scene depicted in the video. This method has a significant positive impact on fields such as online education, remote conferencing, and gaming, as it can better attract user attention and enhance the effectiveness of information delivery and emotional resonance.

[0078] The modular design of the terminal device (selection module, generation module, and signal transmission module) enables the rapid and efficient communication and processing of user needs. The selection module offers multiple odor options covering a wide range of scents, ensuring users can find the appropriate option for different scenarios. The generation module quickly generates odor release commands based on user selections, avoiding cumbersome setup processes. The signal transmission module's instant response capability ensures that odor release commands reach the odor release device promptly, initiating odor release.

[0079] This rapid response capability of the terminal device greatly enhances the smoothness and satisfaction of the user experience. Users can complete the entire process from scent selection to scent release in seconds, without waiting or performing complicated operations.

[0080] Example 4

[0081] like Figures 1 to 6 As shown in the illustration, this application also provides an odor releasing device, which is applied to the above-described odor releasing method. The odor releasing device is used for communication connection with a terminal device, wherein the odor releasing device includes:

[0082] Odor release devices include:

[0083] Multiple raw material storage assemblies, each including a raw material storage 200, each raw material storage 200 being used to hold one type of raw material, and the raw materials in any two raw material storage assemblies 200 being the same or different;

[0084] The control unit 300 is communicatively connected to multiple raw material bins 200 to control whether the raw materials in each raw material bin 200 are released and the amount of raw materials released from each raw material bin 200.

[0085] Specifically, the odor release device provided in this application includes multiple raw material storage assemblies, each of which includes a raw material storage 200. Each raw material storage 200 contains raw materials in liquid form, and the raw materials in any two or more raw material storage assemblies 200 can be the same or different. It also includes a control unit 300, which is a circuit board in this embodiment. Through the control unit 300, one or more raw material storage assemblies 200 of the multiple raw material storage assemblies can be controlled to release raw materials to the outside, as well as the amount of raw materials released, so as to mix and form the original odor type, and control the odor release device to release odor according to the odor release scheme.

[0086] By setting up multiple raw material bins 200, each of which can hold different types of liquid raw materials, the device not only increases the variety of odors it can release, but also allows users to freely select and combine different raw materials according to personal preferences or scenario requirements. The control unit 300 (in this embodiment, a circuit board) can precisely control the release amount and release time of each raw material bin 200. Through the transmission and reception of electronic signals, dynamic management of the raw material bin components is achieved, ensuring that the raw materials are mixed in a predetermined ratio to generate the original odor type desired by the user. This device can intelligently generate odor release schemes based on user selections or scenario information, and adjust the release amount and release sequence of the raw material bins 200 through the control unit 300 to create personalized odors that match specific situations.

[0087] Furthermore, the raw material hopper assembly also includes an outlet component 202 and an atomizing component 400; at least a portion of the outlet component 202 is located within the raw material hopper 200 so that the raw material within the raw material hopper 200 is directed to the outlet component 202; the atomizing component 400 is connected to the outlet component 202 to atomize the raw material on the outlet component 202 to form the original odor; the atomizing component 400 is provided with an odor outlet for allowing the atomized original odor to flow out.

[0088] The odor release device also includes a housing 100, which includes an odor mixing chamber 900. The odor outlets of a plurality of atomizing elements 400 are all connected to the odor mixing chamber 900 so that the original odors flowing out from the odor outlets of at least two of the plurality of atomizing elements 400 are mixed in the odor mixing chamber 900.

[0089] Specifically, the odor release device also includes a housing 100, inside which is an odor mixing chamber 900. The raw material chamber 200 includes a chamber body 201 with an inlet, and the bottom of the chamber body 201 is detachably connected to the housing 100. It also includes a cover that cooperates with the chamber body 201 to open or close the inlet. The cover has a release port. The raw material chamber assembly also includes an outlet component 202 and an atomizing component 400. In this embodiment, the outlet component 202 is a cotton swab. At least a portion of the outlet component 202 is located inside the raw material chamber 200, with one end contacting the bottom of the raw material chamber 200 and the other end extending from the release port. The atomizing component 400 is connected to the atomizing component 400, or the end of the lead-out component 202 away from the material hopper body 201 is flush with the end of the release port away from the bottom of the material hopper body 201 and connected to the atomizing component 400. During use, due to the setting of the lead-out component 202, the raw material in the raw material hopper 200 can be guided to the lead-out component 202. The atomizing component 400 is connected to the lead-out component 202 and can atomize the raw material on the lead-out component 202 to form the original odor. An odor outlet is provided on the atomizing component 400. The odor outlet is used to allow the original odor in the atomized state to flow into the odor mixing chamber 900 so that multiple original odors can be mixed in the odor mixing chamber 900.

[0090] Alternatively, in this embodiment, the atomizing element 400 can be a cover used in conjunction with the hopper body 201. The raw material in the hopper body 201 can be directly guided to the atomizing element 400 through the lead-out component 202. In this way, the atomizing element 400 can both encapsulate the hopper body 201 and transform the liquid raw material into an atomized state.

[0091] Because the raw material hopper 200 inside the housing 100 is detachably connected to the housing 100, users can easily replace the raw material hopper 200. This not only facilitates the replenishment and replacement of raw materials but also reduces the difficulty and cost of equipment maintenance. When the raw material in the hopper 200 is depleted, the user only needs to remove the bottom cover, take out the hopper 200 (hopper body 201), replenish or replace the raw material, and then reinstall it. There is no need to send the entire device for repair or replacement, enhancing the practicality and convenience of the equipment.

[0092] The raw material in the raw material chamber 200 is guided to the atomizing element 400 by the lead-out component 202 (a cotton swab in this embodiment). The cotton swab is in contact with the bottom of the raw material chamber 200, ensuring a stable supply of raw material. The atomizing element 400 atomizes the raw material on the cotton swab, forming the original aroma. Due to the precise design of the lead-out component 202 and the atomizing element 400, the release amount and atomization effect of the raw material can be precisely controlled.

[0093] The original odors released from multiple raw material chambers 200 enter the odor mixing chamber 900 through their respective odor outlets, achieving precise mixing of multiple original odors. The control unit 300 adjusts the working sequence and time of the atomizing components 400 of different raw material chambers 200 according to the odor release plan, ensuring that the original odors enter the odor mixing chamber 900 in a predetermined proportion.

[0094] Example 5

[0095] Furthermore, the raw material hopper assembly also includes an output pipe, the inlet end of which extends into the raw material hopper 200; the atomizing element 400 is connected to the outlet end of the output pipe;

[0096] The output pipe can be switched on and off, so that the on / off state of the output pipe can be controlled by the control unit 300 to control whether the raw materials in the raw material silo 200 are transported from the inlet end to the outlet end.

[0097] Specifically, the raw material silo assembly also includes a pump body disposed within the housing 100 and an output pipe disposed within the raw material silo 200. The inlet end of the output pipe extends into the raw material silo 200 from the release port, and the outlet end of the output pipe extends out from the release port and connects to the atomizing element 400. It also includes multiple on / off valves, which are disposed on the corresponding output pipes. The pump body is connected to the on / off valves so as to control the state of the multiple on / off valves to control the delivery of raw materials in the raw material silo 200 corresponding to each raw material in the scent formula to the atomizing element 400. The atomizing element 400 converts the liquid raw materials into atomized raw materials, thereby delivering multiple atomized raw materials to the scent mixing chamber 900 for mixing.

[0098] The pump body is located inside the housing 100 and connected to the output pipe inside the raw material chamber 200. Through the pump's extraction action, the raw material can be quantitatively and accurately delivered to the atomizing element 400. The control unit 300 issues commands to control the pump to extract the raw material according to the scent formula and guides it through the output pipe, ensuring that the amount of raw material delivered each time meets the requirements of the scent formula, avoiding the problems of raw material waste and scent distortion.

[0099] Multiple on / off valves are installed on the output pipe, each corresponding to a different raw material hopper 200. By controlling the on / off state of the valves, the raw material conveying can be selectively turned on or off, achieving flexibility in raw material selection and facilitating maintenance and troubleshooting.

[0100] The atomizing element 400 receives the raw material delivered by the pump body through the output pipe, rapidly atomizes it into tiny particles, and then sends them into the scent mixing chamber 900 through the scent outlet on the atomizing element 400. After atomization, the raw materials from multiple raw material chambers 200 are dynamically mixed in the scent mixing chamber 900 to form the scent desired by the user.

[0101] Both the inlet and outlet ends of the output pipe are connected to the raw material silo 200 and the atomizing element 400 via release ports, facilitating maintenance and cleaning. Meanwhile, the on / off valve design ensures that raw materials will not leak when not in use, improving the safety of the equipment.

[0102] Example 6

[0103] Furthermore, the raw material silo assembly also includes an output pipe, the inlet end of which extends into the raw material silo 200, and the outlet end of which extends out of the raw material silo 200 and is connected to an atomizing nozzle.

[0104] The power unit has a retractable power end that is in contact with the atomizing nozzle. The power end drives the atomizing nozzle to a pressed state, so that the raw material in the raw material bin 200 is transported from the output pipe to the atomizing nozzle to atomize the raw material and form the original aroma.

[0105] Specifically, the raw material silo assembly also includes an output pipe disposed within the raw material silo 200. The outlet end of the output pipe extends from one end of the raw material silo 200 and is connected to the atomizing nozzle. It also includes a power component, the power end of which is retractable and can abut against the atomizing nozzle. By applying pressure to the atomizing nozzle, the raw material in the raw material silo 200 is transported from the output pipe to the atomizing nozzle, and the atomizing nozzle atomizes the raw material and sprays it into the odor mixing chamber 900 for mixing. In this embodiment, the power component can be a telescopic motor, or a cylinder or an electric telescopic rod, or other retractable components.

[0106] The output pipe in the raw material hopper 200 directs the raw material to the atomizing nozzle, achieving efficient material transport. After receiving the raw material, the atomizing nozzle atomizes it into fine particles, improving the efficiency of the raw material's conversion into gas. A power component (in this embodiment, this can be a telescopic motor, cylinder, or electric telescopic rod) applies adjustable pressure to the atomizing nozzle, promoting the atomization process while ensuring consistent atomization quality. The telescopic nature of the power component allows for flexible adjustments to the equipment based on different raw material characteristics and the desired degree of atomization. The atomized raw material is then sprayed through the odor nozzle into the odor mixing chamber 900, where different raw materials mix thoroughly in the open chamber to form the desired complex odor.

[0107] The power components can take various forms, such as telescopic motors, cylinders, or electric telescopic rods. This diversity of choices not only meets the atomization requirements of different raw materials but also facilitates equipment upgrades and maintenance.

[0108] Furthermore, the atomizing element 400 includes a vibrating plate 401, at least a portion of which is vibratingly disposed. The vibrating plate 401 is connected to the control unit 300 to control the amount of raw material released in each raw material bin 200 by controlling the vibration time of the vibrating plate 401.

[0109] At least a portion of the vibrating plate 401 is vibrating and comes into contact with the raw materials in the raw material bin 200. Vibration atomizes the raw materials, and the vibration time of the vibrating plate 401 directly affects the amount of raw material atomized. A longer vibration time results in a greater amount of atomization, providing a physical basis for precisely controlling the concentration of each aroma. For example, to release a deep apple aroma, the control unit 300 will instruct the vibrating plate 401 to vibrate for a longer time to atomize more apple raw materials, ensuring that the aroma concentration meets expectations.

[0110] The control unit 300 can flexibly adjust the atomization amount of the raw material by changing the vibration time of the vibrating plate 401, thereby controlling the concentration of the odor. The vibration of the vibrating plate 401 not only promotes the atomization of the raw material but also optimizes the size and uniformity of the atomized particles, improving the efficiency and quality of odor release. The control unit 300 can dynamically adjust the vibration time of the vibrating plate 401 according to different odor formulations and user needs, realizing intelligent and personalized operation of the equipment.

[0111] Furthermore, the control unit 300 includes multiple control units, each corresponding to a different raw material silo component.

[0112] Specifically, the control unit 300 includes multiple control units, each corresponding to a multiple raw material silo assembly, so as to enable individual control of each raw material silo assembly to release raw materials from one or more raw material silo assemblies.

[0113] Each raw material compartment component corresponds to a control unit, enabling independent control of each component. It allows for the selective release of one or more raw materials based on the scent formulation requirements. Each control unit can individually adjust the release rate of its corresponding raw material compartment component. By controlling the vibration time of the atomizing element 400 or the pump's suction time, the atomization degree and release rate of each raw material can be finely adjusted to meet the precise concentration requirements of various raw materials in the scent formulation. The control unit 300 integrates multiple control units, capable of simultaneously processing control commands from multiple raw material compartment components. This achieves multi-functional integration of the equipment and also provides possibilities for future functional expansion. The control unit 300 can receive user commands from smart devices (such as mobile phones and computers) and intelligently select raw material compartment components and control the release of raw materials based on user preferences or scenario requirements.

[0114] Furthermore, the odor release device also includes: multiple material channels 500, which are arranged inside the box 100. Each material channel 500 corresponds to a material hopper assembly, so that the material hopper assembly can be installed inside the box 100 through the material channels 500.

[0115] Specifically, the odor release device also includes multiple material channels 500 disposed within the box body 100. Each material channel 500 is in the form of a semi-circular arc, or each material channel 500 may also be in the form of a rectangle. When the material channel 500 is in the form of a rectangle, the inner wall shape of the material channel 500 should be adapted to the outer wall shape of the raw material bin 200. A material channel opening communicating with the material channels 500 is provided on one of the side walls of the box body 100. Through this material channel opening, the raw material bin 200 can be installed inside the box body 100, or the raw material bin 200 can be removed from the box body 100.

[0116] Each feed channel 500 is equipped with a feed port, allowing the raw material bin 200 to be quickly installed into the housing 100, and also facilitating the removal and replacement of the raw material bin 200. When the user needs to replace the raw material bin 200, simply align it with the feed port and gently push the raw material bin 200 along the guide of the feed channel 500 to complete the installation, without the need for complicated tools or professional skills. Conversely, when the raw material is exhausted or needs to be replaced, the raw material bin 200 can be easily removed and replaced with a new one through the same feed port. This design significantly improves the convenience and operational efficiency of the user during equipment use.

[0117] The material channel 500 can be designed as a semi-circular arc or a rectangular shape to match the outer wall shape of the raw material hopper 200, ensuring the stable positioning and good sealing effect of the raw material hopper 200 within the box 100.

[0118] The rational layout of multiple material channels 500 within the housing 100 improves space utilization and makes the overall equipment more compact. As a guide channel for the raw material silo 200, the material channels 500 not only guide the raw material silo 200 to be installed quickly and accurately, but also ensure a reliable connection between the raw material silo 200 and other components within the housing 100 (such as output pipes, on / off valves, etc.).

[0119] Furthermore, the plurality of material channels 500 includes multiple rows of material channel units distributed along a first direction, and each material channel unit includes a plurality of material channels 500 distributed along a second direction, the first direction being perpendicular to the second direction.

[0120] Specifically, the plurality of material channels 500 includes multiple rows of material channel units distributed along a first direction, and each material channel unit includes a plurality of material channels 500 distributed along a second direction, wherein the first direction is perpendicular to the second direction, such as... Figure 4 As shown, the arrangement includes two rows of material channel units arranged opposite each other. The vibrating plate 401 of each row of material channel units is located close to the odor mixing chamber 900. This arrangement can hold a variety of different raw materials.

[0121] The feed channel 500, through multiple rows of feed channel units distributed along the first direction and multiple feed channels 500 in a single row distributed along the second direction, achieves compatibility with various raw materials, allowing for flexible configuration of raw material types and quantities as needed. Assuming the equipment needs to simultaneously support the storage and release of 10 raw materials, it can be designed with two or more rows of feed channel units, each row containing 5 feed channels 500. This ensures sufficient storage of multiple raw materials without occupying excessive space, achieving a balance between equipment function and structure. This arrangement greatly enriches the equipment's odor combination possibilities, meeting users' needs for diverse odor experiences.

[0122] The vibrating plate 401 of each feed channel unit is positioned close to the odor mixing chamber 900, shortening the distance from atomization to mixing of the raw material and improving atomization efficiency and raw material response speed. During odor release, due to the close distance between the vibrating plate 401 and the odor mixing chamber 900, the raw material quickly enters the odor mixing chamber 900 for mixing after atomization, reducing the loss of atomized raw material during transmission and accelerating the speed of odor synthesis. Even in a short time, it can quickly respond to user needs and provide an immediate odor experience.

[0123] The arrangement of the material channel 500 and the design of the vibrating plate 401 close to the odor mixing chamber 900 work together to promote the mixing effect after the raw materials are atomized, thereby improving the quality of odor synthesis.

[0124] Furthermore, there are multiple boxes 100, and each box 100 contains multiple raw material silo components; the multiple boxes 100 are connected.

[0125] Specifically, the odor-releasing device also includes multiple boxes 100, each of which contains multiple raw material hopper components. The multiple boxes 100 can be stacked, arranged side by side, or arranged in a ring. Alternatively, the multiple raw material hopper components in each box can be arranged in different shapes. The specific arrangement method and form can be selected according to the actual situation. The multiple boxes 100 can be connected together by cable ties or adhesive.

[0126] The stacking and side-by-side arrangement of the boxes 100 allows the odor release device to flexibly expand the number of raw material bin components to adapt to different scenarios and needs. For example, for a home entertainment center, users may need up to 20 raw materials to simulate complex odor scenes from movies. In this case, two boxes 100 can be stacked, each holding 10 raw material bin components, or multiple boxes 100 can be arranged side-by-side to achieve the required number of raw material bin components. This modular design not only facilitates the expansion of the device but also ensures its flexibility and adaptability, meeting various user needs.

[0127] The use of cable ties or adhesive tape ensures the secure fixing of multiple boxes 100. The stacked and side-by-side arrangement of the boxes 100 not only optimizes the space occupied by the equipment but also provides versatility in equipment combination, meeting placement needs in different environments and scenarios. Connecting the boxes 100 with cable ties or adhesive tape makes the assembly and maintenance process more convenient, reducing the difficulty of user operation.

[0128] Furthermore, the odor-releasing device also includes: a first mounting groove 600, at least partially disposed on the side wall of the odor mixing chamber 900 away from the raw material chamber 200, for mounting the control unit 300; and / or,

[0129] The third mounting slot 800 is located on the side wall of the odor mixing chamber 900 near the raw material chamber 200 to mount the vibrating plate 401.

[0130] Specifically, the odor-releasing device also includes a first mounting groove 600, disposed within the first sidewall 101 of the box body 100 on the side away from the raw material hopper 200, extending along the length of the box body 100 to mount a circuit board; a second mounting groove 700, disposed on the second sidewall 102 of the box body 100, extending along the width of the box body 100; the first mounting groove 600 and the second mounting groove 700 communicate to accommodate the wires 301 of the circuit board; the first mounting groove 600 and the second mounting groove 700 are L-shaped, wherein the extending direction of the first sidewall 101 is perpendicular to the extending direction of the second sidewall 102; and a third mounting groove 800, disposed on the third sidewall 103 of the box body. The third sidewall 103 is disposed opposite to the second sidewall 102. One end of the atomizing element 400 abuts against the limiting surface of the third mounting groove 800, and the other end of the atomizing element 400 abuts against the end of the second mounting groove 700 away from the first mounting groove 600, so that one side of the atomizing element 400 abuts against the bottom of the plurality of raw material chambers 200. The side of the atomizing element 400 away from the raw material chambers 200 and the side of the first mounting groove 600 near the raw material chambers 200 together form an odor mixing chamber 900 for mixing multiple raw materials. At least a portion of the odor mixing chamber 900 is connected to the outside to release the mixed odor to the outside. A limiting part is provided on the third sidewall 103, and the limiting part has a limiting surface.

[0131] The first mounting slot 600 extends along the length of the housing 100 and is used for mounting the circuit board, ensuring its stable fixation and reasonable layout. The circuit board is mounted in the first mounting slot 600, positioning it away from the raw material silo 200. This avoids moisture damage or the effects of raw material evaporation on the circuit board, and also allows for a more direct connection between the circuit board and the control unit, reducing signal transmission loss and improving control accuracy.

[0132] The L-shaped arrangement and interconnected design of the first mounting slot 600 and the second mounting slot 700 effectively manage and arrange the circuit board wires 301, saving internal space. The atomizing component 400, through contact with the limiting surface of the third mounting slot 800 and the far end of the second mounting slot 700, achieves precise positioning within the housing 100 and effective coupling with the bottom of multiple raw material chambers 200, improving the efficiency and consistency of raw material atomization. The atomizing component 400 and the side of the first mounting slot 600 near the raw material chamber 200 together form an odor mixing chamber 900, which is connected to the outside, achieving efficient mixing of atomized raw materials and rapid odor release.

[0133] Furthermore, the odor release device also includes a cover 105 that works in conjunction with the housing 100. The cover 105 has multiple outlets 106 at positions corresponding to the odor mixing chamber 900, so that the mixed gas in the odor mixing chamber 900 can escape through the multiple outlets 106.

[0134] The detachable connection between the lid 105 and the body 100 can be achieved by snap-fit ​​or by bolts.

[0135] Multiple vents 106 on the lid 105 allow the mixed gas within the odor mixing chamber 900 to escape in a directional and precise manner, effectively controlling the diffusion range and intensity of the odor. When raw materials from different material chambers 200 are atomized by the atomizer 400 and mixed in the odor mixing chamber 900, the mixed gas is released to the outside through the vents 106 on the lid 105. By adjusting the number and size of the vents 106, the flow rate and volume of the gas released from the odor mixing chamber 900 can be controlled, thereby controlling the diffusion range and intensity of the odor in the environment. This meets the user's needs for odor intensity and coverage in different situations, improving user comfort and the applicability of the equipment.

[0136] Furthermore, the odor-releasing device also includes a conductive part 910, which is electrically connected to the control unit 300 for electrical connection with a terminal device; and / or, the odor-releasing device can be wirelessly connected to the terminal device.

[0137] Specifically, a charging port is provided on the outside of the housing 100, which is connected to the first mounting slot 600. The odor releasing device also includes a conductive part 910, which is electrically connected to the control unit 300 for electrical connection with a terminal device; and / or, the odor releasing device can be wirelessly connected to the terminal device, such as via Bluetooth. In this way, the odor releasing device can be powered, or an electronic device can be connected to the odor releasing device, or the power supply can be connected to a data cable, and the data cable can be connected to a non-releasing device, and the odor releasing device can be connected to an electronic device.

[0138] The charging port on the outside of the housing 100 communicates with the first mounting slot 600, allowing a power supply or data cable to pass through the charging port and connect directly to the circuit board or conductive part 910 installed in the first mounting slot 600. This provides flexibility in power supply for the device and enhances its compatibility with external power sources or data cables. When the user needs to charge the odor-releasing device or perform data transmission, they can directly connect the power supply or data cable to the circuit board or conductive part 910 inside the device through the charging port on the outside of the housing 100, without disassembling the device or opening the housing cover 105, simplifying the operation process and improving the ease of use of the device. At the same time, this design ensures the integrity of the internal structure of the device, enhances the durability and protection of the device, and reduces the risk of device damage.

[0139] The electrical connection between the conductive part 910 and the control unit 300 enables seamless integration between the device and the terminal device. Users can remotely and intelligently control the odor release device through terminal devices such as smartphones and smartwatches. When the terminal device establishes an electrical connection with the conductive part 910 through the charging port, the control unit 300 can receive control signals transmitted by the terminal device, such as parameters like odor formula, release time, and atomization intensity, thereby intelligently controlling the working state of the atomizing element 400 to achieve precise odor release.

[0140] Odor-releasing devices support wireless connections with terminal devices, such as via Bluetooth, reducing the need for physical connections and improving the convenience of device interconnection. In the absence of a physical connection, users can establish a stable wireless connection between the terminal device and the odor-releasing device using wireless technologies like Bluetooth, enabling remote control of the device within a certain range. This wireless connection method avoids the constraints of data cables or power cords, giving users greater freedom and flexibility in operating the device, and also facilitating data exchange and control command transmission with other smart electronic devices.

[0141] Furthermore, the odor-releasing device also includes an adsorption element disposed on the outer wall of the housing 100, so as to connect the odor-releasing device to the smart electronic device through the adsorption element.

[0142] Specifically, the odor-releasing device also includes an adsorption element disposed on the outer wall of the housing 100. In this embodiment, the adsorption element can be a magnet, which can connect the odor-releasing device and the smart electronic device together by magnetic attraction. It is worth noting that the adsorption element mentioned in this embodiment can also be other adsorption elements that can connect the odor-releasing device and the smart electronic device together by adsorption, including but not limited to non-stick adhesives.

[0143] The external magnetic attachment of the housing 100 allows for quick and secure positioning and connection to smart electronic devices, such as smartphones or tablets, using magnetic attraction. This simplifies the physical connection process and improves the convenience and stability of the connection. When a user needs to connect the odor-releasing device to a smart electronic device, the magnetic attachment automatically aligns with the magnetic contacts or metal parts on the device, allowing for a quick connection with just a gentle touch. This connection method not only avoids the hassle of finding and inserting data cables but also ensures a stable connection, overcoming the loosening or disconnection issues that can occur with traditional plug-and-play connections.

[0144] It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the exemplary embodiments according to this application. As used herein, the singular form is intended to include the plural form as well, unless the context clearly indicates otherwise. Furthermore, it should be understood that when the terms "comprising" and / or "including" are used in this specification, they indicate the presence of features, steps, operations, devices, components, and / or combinations thereof.

[0145] Unless otherwise specifically stated, the relative arrangement, numerical expressions, and values ​​of the components and steps described in these embodiments do not limit the scope of this invention. It should also be understood that, for ease of description, the dimensions of the various parts shown in the drawings are not drawn to actual scale. Techniques, methods, and devices known to those skilled in the art may not be discussed in detail, but where appropriate, such techniques, methods, and devices should be considered part of the specification. In all examples shown and discussed herein, any specific values ​​should be interpreted as merely exemplary and not as limitations. Therefore, other examples of exemplary embodiments may have different values. It should be noted that similar reference numerals and letters in the following drawings denote similar items; therefore, once an item is defined in one drawing, it need not be further discussed in subsequent drawings.

[0146] In the description of this utility model, it should be understood that the directional terms such as "front, back, up, down, left, right", "horizontal, vertical, horizontal" and "top, bottom" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description. Unless otherwise stated, these directional terms do not indicate or imply that the device or element referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation on the scope of protection of this utility model. The directional terms "inner" and "outer" refer to the inner and outer contours of each component itself.

[0147] For ease of description, spatial relative terms such as "above," "on top of," "on the upper surface of," "above," etc., are used herein to describe the spatial positional relationship of a device or feature as shown in the figures to other devices or features. It should be understood that spatial relative terms are intended to encompass different orientations in use or operation beyond the orientation of the device as described in the figures. For example, if the device in the figures were inverted, a device described as "above" or "on top of" other devices or structures would subsequently be positioned as "below" or "under" other devices or structures. Thus, the exemplary term "above" can include both "above" and "below." The device may also be positioned in other different ways (rotated 90 degrees or in other orientations), and the spatial relative descriptions used herein will be interpreted accordingly.

[0148] Furthermore, it should be noted that the use of terms such as "first" and "second" to define components is merely for the purpose of distinguishing the corresponding components. Unless otherwise stated, the above terms have no special meaning and therefore cannot be construed as limiting the scope of protection of this utility model.

[0149] The above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. An odor-releasing device, characterized in that, include: Multiple raw material storage assemblies, each raw material storage assembly including a raw material storage silo (200), each raw material storage silo (200) being used to hold a raw material, and the raw materials in any two raw material storage silos (200) being the same or different; A control unit (300) is communicatively connected to a plurality of the raw material bins (200) to control whether the raw materials in each raw material bin (200) are released and the amount of raw materials released in each raw material bin (200).

2. The odor-releasing device according to claim 1, characterized in that, The raw material silo assembly further includes an outlet component (202) and an atomizing component (400); at least a portion of the outlet component (202) is located within the raw material silo (200) to guide the raw material within the raw material silo (200) onto the outlet component (202); the atomizing component (400) is connected to the outlet component (202) to atomize the raw material on the outlet component (202) to form an original odor; the atomizing component (400) is provided with an odor outlet for allowing the atomized original odor to flow out. The odor release device further includes a housing (100) including an odor mixing chamber (900); the odor outlets of the plurality of atomizing elements (400) are all connected to the odor mixing chamber (900) so that the original odors flowing out of the odor outlets of at least two of the plurality of atomizing elements (400) are mixed in the odor mixing chamber (900).

3. The odor-releasing device according to claim 2, characterized in that, The raw material silo (200) includes: The hopper body (201) has a feed inlet, and the bottom of the hopper body (201) is detachably connected to the fourth side wall (104) of the box body (100); A cover, which is used in conjunction with the hopper body (201) to open or close the feed inlet, and the cover is provided with a release port; The lead-out component (202) is located inside the hopper body (201).

4. The odor-releasing device according to claim 2, characterized in that, The raw material silo assembly also includes an output pipe, the inlet end of which extends into the raw material silo (200); the atomizing element (400) is connected to the outlet end of the output pipe; The output pipe can be switched on and off, so that the on / off state of the output pipe can be controlled by the control unit (300) to control whether the raw material in the raw material silo (200) is transported from the inlet end to the outlet end.

5. The odor-releasing device according to claim 1, characterized in that, The raw material silo assembly also includes an output pipe, the inlet end of which extends into the raw material silo (200), and the outlet end of which extends out from the raw material silo (200) and is connected to an atomizing nozzle; A power component, wherein the power end of the power component is retractably disposed and is disposed in contact with the atomizing nozzle, so as to drive the atomizing nozzle to be in a pressed state by the power end, so that the raw material in the raw material bin (200) is transported from the output pipe to the atomizing nozzle to atomize the raw material and form the original aroma.

6. The odor-releasing device according to claim 2, characterized in that, The atomizing element (400) includes a vibrating plate (401), at least a portion of which is vibratingly disposed, the vibrating plate (401) being connected to the control unit (300) to control the release amount of the raw material in each of the raw material bins (200) by controlling the vibration time of the vibrating plate (401).

7. The odor-releasing device according to claim 6, characterized in that, The control unit (300) includes multiple control units, each of which is configured in a one-to-one correspondence with a plurality of raw material silo components.

8. The odor-releasing device according to claim 2, characterized in that, The odor-releasing device also includes: Multiple material channels (500) are disposed within the housing (100). Each material channel (500) corresponds to a material hopper assembly, so that the material hopper assembly can be installed within the housing (100) through the material channels (500).

9. The odor-releasing device according to claim 8, characterized in that, The plurality of material channels (500) include multiple rows of material channel units distributed along a first direction, each material channel unit including a plurality of material channels (500) distributed along a second direction, the first direction being perpendicular to the second direction.

10. The odor-releasing device according to claim 2, characterized in that, There are multiple boxes (100), and each box (100) contains multiple raw material silo components; the multiple boxes (100) are connected.

11. The odor-releasing device according to claim 6, characterized in that, The odor-releasing device also includes: A first mounting slot (600) is at least partially disposed on the side wall of the odor mixing chamber (900) away from the raw material chamber (200) for mounting the control unit (300); and / or, The third mounting slot (800) is provided on the side wall of the odor mixing chamber (900) near the raw material chamber (200) to mount the vibrating plate (401).

12. The odor-releasing device according to claim 2, characterized in that, The odor release device also includes a cover (105) that works in conjunction with the box body (100). The cover (105) has a plurality of outlets (106) at a position corresponding to the odor mixing chamber (900) so that the mixed gas in the odor mixing chamber (900) can escape through the plurality of outlets (106).

13. The odor-releasing device according to claim 1, characterized in that, The odor-releasing device further includes a conductive part (910) electrically connected to the control unit (300); and / or, the odor-releasing device can be wirelessly connected to a terminal device.

14. The odor-releasing device according to claim 2, characterized in that, The odor-releasing device also includes: An adsorption element is disposed on the outer wall surface of the housing (100) to connect the odor-releasing device to a smart electronic device via the adsorption element.