INDEXING OF PORTABLE PERFUME DEVICE

Abstract

The present disclosure provides a smart perfume emission device (100) that integrates indexing for optimized fragrance control, particularly in portable perfume systems. The device includes a housing unit (102) designed to accommodate a liquid perfume reservoir (104). A sensor module (106) within the housing detects fragrance concentration in the surrounding air. An actuator unit (108), operatively connected to the sensor module, adjusts a spray nozzle (110) based on detected fragrance levels. A control unit (112) regulates the emission of perfume, using real-time data from the sensor module to maintain the desired fragrance intensity. This system enhances fragrance distribution by adapting to environmental conditions.

Specification

Description:Field of the Invention


The present disclosure relates to portable perfume devices. Particularly, the present disclosure relates to systems for indexing and controlling fragrance emission through sensor-based feedback mechanisms in smart perfume devices.
Background
The background description includes information that may be useful in understanding the present invention. It is not an admission that any of the information provided herein is prior art or relevant to the presently claimed invention, or that any publication specifically or implicitly referenced is prior art.
Fragrance emission devices are commonly used to enhance the scent of indoor environments in homes, offices, and public spaces. Conventional perfume or air freshener dispensers often rely on manual activation or preset timers to release fragrance into the air. These systems generally emit perfume at fixed intervals or amounts, irrespective of the actual fragrance concentration already present in the environment. As a result, conventional systems may either over-saturate the air with perfume, leading to discomfort or waste, or under-saturate the air, failing to maintain the desired fragrance level over time. The lack of dynamic control in such systems reduces efficiency and may fail to adapt to varying room sizes, ventilation conditions, or individual preferences.
One known system uses manual spray devices or mechanical pumps that require users to activate them each time fragrance is needed. While such systems provide user control, they lack the ability to automatically adjust to changing conditions, requiring constant human intervention for effective fragrance management. Additionally, the emission is usually uniform and cannot be adjusted based on the actual scent concentration in the room.
Another well-known system involves automatic air fresheners that release fragrance at regular intervals through a timed mechanism. These devices, while reducing the need for manual operation, lack sensors to detect the fragrance concentration in the ambient air. As a result, such systems may continue to emit perfume even when the air is already sufficiently scented, causing unnecessary perfume consumption and potential sensory overload in smaller or enclosed spaces.
In light of the above discussion, there exists an urgent need for solutions that overcome the problems associated with conventional systems and/or techniques for perfume emission. Specifically, a smart perfume emission device is required that dynamically adjusts perfume release based on real-time fragrance concentration in the ambient air, ensuring efficient and consistent scent levels without overuse or waste.
All references, including publications, patent applications, and patents, cited herein are hereby incorporated by reference to the same extent as if each reference were individually and specifically indicated to be incorporated by reference and were set forth in its entirety herein.
Summary
Various objects, features, and advantages of the disclosed subject matter can be more fully appreciated with reference to the following detailed description of the disclosed subject matter when considered in connection with the following drawings, in which like reference numerals identify like elements.
The present disclosure relates to portable perfume devices. Particularly, the present disclosure relates to systems for indexing and controlling fragrance emission through sensor-based feedback mechanisms in smart perfume devices.
An objective of the present disclosure is to provide a smart perfume emission device to regulate perfume emission based on fragrance concentration in ambient air. The system of the present disclosure aims to achieve efficient perfume emission through automatic adjustment based on environmental factors.
In an aspect, the present disclosure provides a smart perfume emission device comprising a housing unit accommodating a liquid perfume reservoir. A sensor module is positioned within the housing unit and detects fragrance concentration in ambient air. An actuator unit is operatively coupled to the sensor module to adjust a spray nozzle located at one end of the housing unit. A control unit is connected to the actuator unit and regulates perfume emission based on data received from the sensor module.
Furthermore, the sensor module further includes an air quality sensor to measure particulate matter and volatile organic compounds, enhancing the accuracy of the fragrance concentration measurements. Moreover, the actuator unit comprises a motorized pump to control the flow rate of liquid perfume from the reservoir to the spray nozzle, enabling precise emission control. Additionally, the spray nozzle is provided with a variable aperture to modify the spray pattern based on input from the control unit. The control unit is also provided with a wireless communication module for transmitting fragrance concentration data to an external device, thereby facilitating remote monitoring and adjustment. Moreover, the sensor module detects ambient temperature and humidity, transmitting the data to the control unit for dynamic perfume emission adjustment.
Additionally, the actuator unit comprises a feedback loop for the continual adjustment of the spray nozzle position based on real-time data from the sensor module. The liquid perfume reservoir is detachable and equipped with a locking unit for secure placement within the housing unit during operation. Further, the spray nozzle incorporates a self-cleaning mechanism to prevent clogging from repeated use. The actuator unit includes a vibration dampening unit to enable smooth adjustments of the spray nozzle during operation.

Brief Description of the Drawings


The features and advantages of the present disclosure would be more clearly understood from the following description taken in conjunction with the accompanying drawings in which:
FIG. 1 illustrates a smart perfume emission device (100), in accordance with the embodiments of the pressent disclosure.
FIG. 2 illustrates sequential diagram of a smart perfume emission device (100), in accordance with the embodiments of the pressent disclosure.
Detailed Description
The following is a detailed description of exemplary embodiments to illustrate the principles of the invention. The embodiments are provided to illustrate aspects of the invention, but the invention is not limited to any embodiment. The scope of the invention encompasses numerous alternatives, modifications and equivalent; it is limited only by the claims.
In view of the many possible embodiments to which the principles of the present discussion may be applied, it should be recognized that the embodiments described herein with respect to the drawing figures are meant to be illustrative only and should not be taken as limiting the scope of the claims. Therefore, the techniques as described herein contemplate all such embodiments as may come within the scope of the following claims and equivalents thereof.
The detailed description is described with reference to the accompanying figures. In the figures, the left-most digit(s) of a reference number identifies the figure in which the reference number first appears. The use of the same reference numbers in different instances in the description and the figures may indicate similar or identical items.
Pursuant to the "Detailed Description" section herein, whenever an element is explicitly associated with a specific numeral for the first time, such association shall be deemed consistent and applicable throughout the entirety of the "Detailed Description" section, unless otherwise expressly stated or contradicted by the context.
The present disclosure relates to portable perfume devices. Particularly, the present disclosure relates to systems for indexing and controlling fragrance emission through sensor-based feedback mechanisms in smart perfume devices.
Pursuant to the "Detailed Description" section herein, whenever an element is explicitly associated with a specific numeral for the first time, such association shall be deemed consistent and applicable throughout the entirety of the "Detailed Description" section, unless otherwise expressly stated or contradicted by the context.
As used herein, the term "housing unit" refers to a structure that accommodates various components of the smart perfume emission device. Such a housing unit provides an enclosed space to contain a liquid perfume reservoir while also serving as a structural framework for mounting other elements, including sensors, actuator units, and control mechanisms. The housing unit is fabricated from materials suitable for containing liquids, preventing leakage, and withstanding external environmental conditions. The housing unit may also provide access points for refilling or replacing the liquid perfume reservoir and may include sections for routing electrical connections or pathways for liquid movement. Additionally, the housing unit may be designed in various shapes and sizes to achieve optimal performance, aesthetic appeal, and ergonomic handling. The housing unit thus serves as the primary containment structure for the efficient operation of the smart perfume emission device, ensuring all components are held securely in their designated positions and are easily accessible for maintenance or replacement.
As used herein, the term "liquid perfume reservoir" refers to a container designed to hold a quantity of liquid perfume within the smart perfume emission device. Said reservoir is structured to store and supply liquid perfume to the actuator unit for emission through the spray nozzle. The liquid perfume reservoir is made from materials that are compatible with the stored perfume to prevent any chemical reaction or degradation. The reservoir may be detachable to facilitate easy refilling or replacement when the liquid perfume is exhausted. Furthermore, such a reservoir may be sealed adequately to prevent evaporation or spillage, ensuring consistent availability of the liquid perfume. The liquid perfume reservoir may vary in capacity based on the desired usage frequency and device size, and is connected to other device components through secure pathways to enable effective transfer of liquid perfume during operation.
As used herein, the term "sensor module" refers to a sensor assembly positioned within the housing unit, designed to detect fragrance concentration in the ambient air surrounding the smart perfume emission device. Such sensors are sensitive to the presence of airborne particles associated with the perfume fragrance and provide real-time data corresponding to the detected concentration levels. The sensor assembly may include additional sensors to monitor other environmental parameters such as air quality, particulate matter, volatile organic compounds, temperature, and humidity. These measurements enable dynamic adjustment of perfume emission based on changing ambient conditions. Furthermore, the sensor assembly is operatively connected to the control unit to transmit detected data, allowing responsive operation of other device components for efficient perfume emission.
As used herein, the term "actuator unit" refers to a mechanical assembly operatively coupled to the sensor assembly, structured to adjust the position and operation of the spray nozzle within the smart perfume emission device. The actuator unit receives input data from the control unit and translates such data into mechanical movements to control the spray pattern, flow rate, and direction of the emitted perfume. Said actuator unit may comprise components such as motorized pumps, servos, or other mechanical devices for precise modulation of the spray nozzle. Additionally, the actuator unit may include a feedback loop for real-time adjustments based on sensor data and may incorporate mechanisms for vibration dampening to ensure smooth operation. The actuator unit is designed for durability and responsiveness to enable controlled perfume release as per environmental and user requirements.
As used herein, the term "spray nozzle" refers to the dispensing component positioned at one end of the housing unit for releasing liquid perfume into the ambient air. The spray nozzle is operatively controlled by the actuator unit to emit the liquid perfume in a fine mist or spray, based on the data received from the control unit. Such a nozzle may include a variable aperture to adjust the pattern, density, and coverage of the perfume spray, thereby enhancing distribution efficiency and fragrance dispersion. The spray nozzle may be constructed from materials that resist clogging or wear due to repeated use, and it may include a self-cleaning mechanism to maintain performance and prevent blockage over time. Furthermore, the design of the spray nozzle allows precise control over the emission direction and rate, contributing to the smart regulation of perfume dispersion.
As used herein, the term "control unit" refers to an electronic control system connected to the actuator unit and receiving data from the sensor assembly within the smart perfume emission device. The control unit processes the received data to regulate perfume emission parameters such as flow rate, spray pattern, and emission timing. Such a control unit may include processing circuitry, memory, and a wireless communication module to enable remote monitoring and adjustments through external devices. The control unit dynamically interprets sensor data, adjusting the actuator's operation to maintain optimal fragrance concentration in the surrounding environment. The control unit may also provide user interface elements for manual operation or adjustment of device settings as per individual preferences and environmental conditions.
FIG. 1 illustrates a smart perfume emission device (100), in accordance with the embodiments of the pressent disclosure. In an embodiment, the housing unit 102 forms a primary structure for accommodating various components of the smart perfume emission device 100. The housing unit 102 is constructed from materials suitable for containing liquids, protecting internal components from external elements, and maintaining structural integrity throughout operation. The housing unit 102 may comprise one or more compartments to hold and support a liquid perfume reservoir 104, which stores liquid perfume to be emitted as fragrance. The housing unit 102 provides access points or openings for the insertion, removal, or replacement of the liquid perfume reservoir 104. Additionally, the housing unit 102 may incorporate sections to route electrical wiring or pathways for the movement of liquid perfume to the spray nozzle 110. The housing unit 102 is designed to be compatible with other components, such as the sensor module 106, actuator unit 108, and control unit 112, allowing secure attachment and ensuring their correct positioning within the housing unit 102. Such housing unit 102 may vary in size and shape, based on design preferences and ergonomic considerations, to achieve an optimal balance between portability and functional operation of the smart perfume emission device 100.
In an embodiment, the sensor module 106 is positioned within the housing unit 102 and is operatively linked to detect fragrance concentration in the ambient air surrounding the smart perfume emission device 100. The sensor module 106 may be configured to detect particles associated with perfume fragrance and generate data representing the detected concentration levels. Such sensor module 106 may comprise additional sensors to measure environmental factors such as particulate matter, volatile organic compounds, temperature, and humidity. The sensor module 106 may employ sensitive components to provide accurate readings, which are transmitted to the control unit 112 for processing. Furthermore, the sensor module 106 may be positioned strategically within the housing unit 102 to effectively monitor ambient air around the device 100 and avoid interference from internal operations. The housing of the sensor module 106 may include protective coverings to shield sensor components from damage while allowing air passage to enable fragrance detection. The sensor module 106 may operate continuously or at intervals to enable responsive adjustments to the perfume emission.
In an embodiment, the actuator unit 108 is operatively coupled to the sensor module 106 and configured to adjust the spray nozzle 110 of the smart perfume emission device 100. The actuator unit 108 comprises mechanical components, such as motors, pumps, or servos, designed to translate electronic control signals into physical movements for regulating the flow and emission of liquid perfume from the reservoir 104. The actuator unit 108 controls the spray nozzle 110, which is positioned at one end of the housing unit 102 to emit the liquid perfume into the surrounding environment. The actuator unit 108 adjusts the spray nozzle 110 based on input received from the control unit 112, which processes data from the sensor module 106. The actuator unit 108 may regulate parameters such as the direction, pattern, and intensity of the emitted spray by altering the position or aperture of the spray nozzle 110. Additionally, the actuator unit 108 may include a feedback mechanism to enable real-time adjustments to the spray nozzle 110 based on environmental changes or user preferences. Vibration dampening components within the actuator unit 108 may be utilized to ensure smooth operation and precise control over liquid perfume emission.
In an embodiment, the control unit 112 is operatively connected to the actuator unit 108 and is configured to regulate perfume emission based on data received from the sensor module 106. The control unit 112 processes the real-time data provided by the sensor module 106 regarding fragrance concentration, air quality, and other environmental conditions. Based on this data, the control unit 112 issues commands to the actuator unit 108 to dynamically adjust the spray nozzle 110, modifying the release of liquid perfume to maintain optimal fragrance levels in the ambient air. The control unit 112 may include processing circuitry, memory, and communication interfaces to execute control algorithms and facilitate device operations. Additionally, the control unit 112 may incorporate a wireless communication module for transmitting sensor data to external devices, enabling remote monitoring and control of the perfume emission device 100. The control unit 112 may provide programmable options for customizing perfume emission patterns, schedules, and intensity levels according to user preferences or predetermined settings.
In an embodiment, the sensor module 106 includes an air quality sensor that measures not only the fragrance concentration but also particulate matter and volatile organic compounds present in the ambient air. The air quality sensor detects and analyzes particles of varying sizes, ranging from fine particulate matter to larger pollutants, enabling a comprehensive assessment of air quality around the smart perfume emission device 100. By evaluating volatile organic compounds, the sensor provides additional data on substances such as gases and chemical vapors, which may influence the perception and dispersion of fragrance emitted by the device. The integration of this air quality sensor allows the sensor module 106 to provide a detailed profile of the surrounding air environment. The sensor is electronically linked to the control unit 112, transmitting real-time measurements that the control unit 112 uses to make adjustments to the perfume emission. Additionally, the air quality sensor may be calibrated to detect specific thresholds of particulate matter and volatile organic compounds, enabling tailored fragrance release based on environmental conditions. The sensor may be strategically positioned within the housing unit 102 to maximize exposure to ambient air while protecting internal sensor elements from damage or contamination.
In an embodiment, the actuator unit 108 comprises a motorized pump that controls the flow rate of liquid perfume from the liquid perfume reservoir 104 to the spray nozzle 110. The motorized pump is designed to facilitate regulated movement of the liquid perfume, enabling precise control over the quantity and frequency of fragrance emitted. The motorized pump operates based on input signals received from the control unit 112, which processes data provided by the sensor module 106. The motorized pump may include a small motor and a pumping mechanism, such as a diaphragm pump, peristaltic pump, or piston pump, that draws the liquid perfume from the reservoir 104 and propels it toward the spray nozzle 110. The flow rate can be adjusted dynamically to alter the concentration of fragrance released, providing customized emission patterns based on user preferences or environmental needs. The pump is connected to fluid pathways or tubing within the housing unit 102, ensuring an efficient and controlled transfer of liquid perfume. The pump is designed to operate quietly and efficiently to maintain a consistent spray pattern.
In an embodiment, the spray nozzle 110 comprises a variable aperture that is adjustable based on input received from the control unit 112. The variable aperture controls the size, shape, and distribution of the perfume spray emitted into the ambient air. The control unit 112 sends signals to the actuator unit 108, which, in turn, manipulates the variable aperture of the spray nozzle 110. This allows the spray nozzle 110 to generate different spray patterns, such as a fine mist, a concentrated jet, or a wide dispersal, depending on the desired fragrance intensity and area of coverage. The variable aperture can change dynamically in response to changing environmental factors detected by the sensor module 106, such as fragrance concentration, air quality, temperature, and humidity. The nozzle may include components like a rotating disk, movable shutters, or an expandable diaphragm, which alter the aperture size and directionality of the spray. The spray nozzle 110 is designed to be corrosion-resistant and durable, providing consistent performance without clogging or degradation over time.
In an embodiment, the control unit 112 includes a wireless communication module that transmits fragrance concentration data and other operational parameters to an external device for remote monitoring and adjustment. The wireless communication module may employ technologies such as Bluetooth, Wi-Fi, Zigbee, or cellular communication to establish a connection with smartphones, tablets, computers, or cloud-based servers. This connection enables users or remote systems to access real-time data on fragrance concentration, air quality, temperature, and humidity, as detected by the sensor module 106. Additionally, the wireless communication module facilitates remote control of the perfume emission device 100, allowing users to adjust settings, emission patterns, and spray intervals from a distance. The communication module may also provide alerts or notifications regarding low liquid perfume levels, maintenance requirements, or environmental changes. Such a wireless communication module is embedded within the control unit 112 and may include antennas, transmitters, and receivers to facilitate reliable data transfer and communication over varying distances.
In an embodiment, the sensor module 106 is further capable of detecting ambient temperature and humidity and transmitting said data to the control unit 112 for dynamic adjustment of perfume emission. By continuously monitoring temperature and humidity, the sensor module 106 allows the control unit 112 to regulate the rate, pattern, and duration of fragrance release based on environmental conditions. The temperature sensor within the sensor module 106 measures the ambient temperature, providing data that influences the volatility and diffusion rate of the liquid perfume. Meanwhile, the humidity sensor evaluates the moisture content in the air, which can affect the persistence and spread of the emitted fragrance. The control unit 112 receives this data and processes it to alter the operation of the actuator unit 108 and spray nozzle 110 accordingly. This real-time responsiveness enhances the smart functionality of the perfume emission device 100, ensuring optimal fragrance release based on current environmental conditions.
In an embodiment, the actuator unit 108 comprises a feedback loop that continually adjusts the position of the spray nozzle 110 based on real-time data from the sensor module 106. The feedback loop allows the actuator unit 108 to perform iterative adjustments to the spray pattern, angle, and direction in response to changing fragrance concentration, air quality, temperature, and humidity detected by the sensor module 106. The feedback loop is an integrated control mechanism that enables the actuator unit 108 to perform continuous self-regulation, maintaining consistent and optimal perfume emission. The actuator unit 108 is operatively connected to the control unit 112, which processes the sensor data and provides corresponding signals to the feedback loop, directing adjustments in the spray nozzle 110. The feedback loop may include sensors, actuators, and controllers that work cohesively to fine-tune the spray nozzle 110's operation in real-time.
In an embodiment, the liquid perfume reservoir 104 is designed to be detachable and includes a locking unit to secure the reservoir within the housing unit 102 during operation. The detachable nature of the reservoir 104 facilitates easy removal for refilling, replacement, or maintenance without disrupting the operation of the smart perfume emission device 100. The locking unit ensures that the reservoir 104 remains securely in place within the housing unit 102, preventing accidental spillage or dislodgement during operation. The locking unit may include mechanical components such as clips, latches, or bayonet fittings that engage with corresponding features within the housing unit 102. The reservoir 104 may be designed in various shapes and sizes to accommodate different volumes of liquid perfume, providing versatility and ease of use. The material of the reservoir 104 is selected to be compatible with the perfume liquid, resistant to corrosion, and suitable for repeated handling.
In an embodiment, the spray nozzle 110 further comprises a self-cleaning mechanism that prevents clogging due to repeated use of the smart perfume emission device 100. The self-cleaning mechanism is integrated into the nozzle structure and operates automatically or upon user command to remove any accumulated residue, build-up, or blockages caused by liquid perfume particles. The self-cleaning mechanism may include features such as movable brushes, scraping elements, or pressurized air jets that clean the nozzle aperture and internal pathways. This mechanism ensures consistent and unobstructed spray patterns, maintaining the performance and reliability of the spray nozzle 110 over time. The self-cleaning mechanism is activated based on predefined intervals, user preferences, or in response to detected clogging.
In an embodiment, the actuator unit 108 includes a vibration dampening unit that facilitates smooth adjustment of the spray nozzle 110 during operation. The vibration dampening unit reduces mechanical oscillations or disturbances caused by movements of the actuator components, ensuring that the adjustments to the spray nozzle 110 are precise and steady. Such a vibration dampening unit may include materials or structures that absorb vibrations, such as rubber mounts, springs, or damping fluids, which isolate and mitigate unwanted motion. By minimizing vibrations, the actuator unit 108 maintains accurate control over the spray nozzle 110's position and spray pattern, enhancing the stability of perfume emission. The vibration dampening unit is integrated within the actuator unit 108, ensuring reliable operation without causing noise or affecting other components of the smart perfume emission device 100.
The disclosed smart perfume emission device (100) introduces a system for indexing and optimizing the emission of perfume, with particular emphasis on portability and environmental adaptation. The housing unit (102) accommodates a liquid perfume reservoir (104), from which fragrance is emitted through a spray nozzle (110) positioned at one end of the housing. The device incorporates a sensor module (106) that continuously monitors the ambient fragrance concentration, providing real-time feedback on the current scent level in the air. This sensor is critical for ensuring that the device releases the right amount of perfume, avoiding both under- and over-dispersion of the fragrance.
The actuator unit (108) works in conjunction with the sensor module to adjust the position and output of the spray nozzle (110), ensuring that the fragrance is emitted in accordance with the detected environmental conditions. When the sensor module detects that the fragrance concentration has fallen below a preset threshold, the actuator triggers the spray nozzle to emit a controlled burst of perfume, maintaining the desired scent level. Conversely, if the fragrance concentration is too high, the actuator limits or halts the emission, thereby preventing excessive fragrance release.
The control unit (112) serves as the central processor, regulating the overall operation of the device. It collects data from the sensor module and dynamically adjusts the actuator's response based on indexed fragrance levels. This indexing mechanism allows the device to adapt to different environments, such as larger or smaller rooms, and maintain optimal scent distribution. The device's ability to automatically adjust fragrance levels based on real-time data makes it ideal for personal use in various settings, from offices to homes, ensuring consistent and pleasant fragrance experiences. By integrating smart control and environmental sensing, this perfume device optimizes fragrance emission, prolonging the life of the perfume while enhancing user convenience.
FIG. 2 illustrates sequential diagram of a smart perfume emission device (100), in accordance with the embodiments of the pressent disclosure.
The sequential diagram illustrates the flow of operations within a smart perfume emission device. The process begins with the sensor module (106), which detects fragrance concentration in the ambient air. Upon detection, the sensor module transmits this data to the control unit (112). The control unit processes the received information and determines the appropriate adjustments to be made. It then sends commands to the actuator unit (108) based on the data from the sensor module. The actuator unit responds to these instructions by adjusting the spray nozzle (110), which is positioned at the end of the housing unit. The nozzle is then manipulated to emit the perfume into the environment in a controlled manner. Each step in the sequence is represented with arrows indicating the flow of information and control between the components, ensuring the correct regulation of perfume emission as intended by the device's design.
In an embodiment, housing unit 102 provides a structural framework that securely accommodates the liquid perfume reservoir 104 and other critical components, such as sensor module 106, actuator unit 108, and control unit 112. The placement of each component within housing unit 102 ensures effective protection from external elements and facilitates efficient interaction among the components. The arrangement of liquid perfume reservoir 104 within housing unit 102 allows for easy replacement or refilling, ensuring continuous operation. The positioning of sensor module 106 within housing unit 102 optimizes detection of fragrance concentration in the ambient air, while actuator unit 108 is mounted for seamless control of spray nozzle 110. Such spray nozzle is positioned at the housing unit's 102 end for optimal fragrance dispersion. Control unit 112 is operatively connected to all active components, streamlining the regulation of perfume emission based on real-time data from sensor module 106. This collective configuration contributes to an integrated device with efficient functionality and minimal interference between components.
In an embodiment, sensor module 106 includes an air quality sensor that provides additional data on particulate matter and volatile organic compounds present in the ambient air. This capability enables the sensor module 106 to detect not just the perfume fragrance but also other environmental pollutants or organic substances that may influence the perception of fragrance. The data on particulate matter allows sensor module 106 to respond to varying levels of air pollution, while detection of volatile organic compounds contributes to a more accurate assessment of the overall air composition. Such comprehensive air quality monitoring enables control unit 112 to make precise adjustments to the perfume emission, ensuring an optimal fragrance experience that is responsive to changing environmental conditions. By providing multifaceted air data, sensor module 106 enhances the device's ability to maintain consistent and appropriate fragrance levels.
In an embodiment, actuator unit 108 comprises a motorized pump that effectively controls the flow rate of liquid perfume from liquid perfume reservoir 104 to spray nozzle 110. Such motorized pump enables consistent regulation of liquid transfer, providing controlled emission of fragrance based on the required rate and pattern. By dynamically adjusting the flow rate, actuator unit 108 can accommodate various operational modes, such as continuous spray or intermittent bursts, allowing customization based on user preferences or environmental factors detected by sensor module 106. The motorized pump is responsive to control signals from control unit 112, facilitating real-time adjustments to perfume emission. This precise control over liquid flow rate minimizes waste, improves device efficiency, and ensures a consistent fragrance output that can be modulated in accordance with sensor feedback.
In an embodiment, spray nozzle 110 comprises a variable aperture designed to adjust the spray pattern based on input received from control unit 112. Such variable aperture allows for dynamic control over the size, shape, and direction of the emitted perfume mist. This adjustability enables the device to emit fine mists for wide dispersal or concentrated jets for targeted applications, optimizing the perfume coverage for different environments and user preferences. By controlling the aperture size and spray pattern, spray nozzle 110 provides flexibility in perfume distribution, enhancing the overall diffusion and sensory perception of fragrance in a space. The control signals from control unit 112 dictate how spray nozzle 110 should adjust its aperture, enabling seamless changes in emission style and volume.
In an embodiment, control unit 112 includes a wireless communication module that enables remote monitoring and adjustment of the perfume emission device 100. Such wireless communication module facilitates the transfer of fragrance concentration data and operational parameters to external devices like smartphones, tablets, or computers, allowing users to access real-time information and control the device from a distance. This remote accessibility enhances user interaction with the device, allowing for on-the-go adjustments to emission settings, schedules, and fragrance preferences. Control unit 112 also supports alerts and notifications about perfume levels, environmental changes, or maintenance needs, improving the operational convenience and adaptability of the device.
In an embodiment, sensor module 106 detects ambient temperature and humidity, providing control unit 112 with comprehensive environmental data for dynamic adjustment of perfume emission. The ability to sense temperature influences the rate of perfume evaporation, while humidity levels affect the dispersion and persistence of the fragrance in the air. By analyzing both temperature and humidity, sensor module 106 allows control unit 112 to modify the spray parameters to maintain optimal fragrance levels in varying environmental conditions. This adjustment may involve changes in spray intensity, pattern, or duration, ensuring that the perfume emission remains consistent and effective despite fluctuations in ambient factors.
In an embodiment, actuator unit 108 incorporates a feedback loop that allows for continual adjustment of spray nozzle 110 based on real-time data from sensor module 106. Such feedback loop facilitates a closed control system wherein actuator unit 108 is able to adaptively modify the position, angle, and spray pattern of spray nozzle 110 as environmental conditions change. This responsive mechanism enables immediate adjustments to maintain the desired fragrance concentration and distribution in the air, providing stability and adaptability in perfume emission. The feedback loop improves the real-time responsiveness of actuator unit 108, ensuring that the fragrance dispersion matches the optimal requirements determined by sensor data.
In an embodiment, liquid perfume reservoir 104 is detachable and includes a locking unit that securely fastens the reservoir within housing unit 102 during operation. The detachable design allows for easy refilling or replacement of liquid perfume without disrupting the functioning of the device. Such locking unit prevents accidental spillage or dislodgement of the reservoir, maintaining the integrity of the device's internal structure and ensuring consistent liquid supply to spray nozzle 110. The detachable nature of the reservoir offers flexibility in maintenance and enables quick replenishment of perfume, supporting continuous and efficient device use.
In an embodiment, spray nozzle 110 includes a self-cleaning mechanism that prevents clogging caused by repeated use or accumulation of perfume residue. The self-cleaning mechanism operates to remove any build-up within the nozzle, ensuring an unobstructed pathway for liquid perfume to be emitted. This feature maintains consistent spray performance and longevity












I/We Claims


1. A smart perfume emission device (100) comprising:
a housing unit (102) configured to accommodate a liquid perfume reservoir (104);
a sensor module (106) positioned within said housing unit (102) and configured to detect fragrance concentration in ambient air;
an actuator unit (108) operatively coupled to said sensor module (106) and configured to adjust a spray nozzle (110) positioned at one end of said housing unit (102); and
a control unit (112) connected to said actuator mechanism (108), wherein said control unit (112) regulates perfume emission based on data from said sensor module (106).
2. The smart perfume emission device (100) of claim 1, wherein said sensor module (106) further comprises an air quality sensor configured to measure particulate matter and volatile organic compounds in addition to fragrance concentration.
3. The smart perfume emission device (100) of claim 1, wherein said actuator unit (108) comprises a motorized pump configured to control the flow rate of liquid perfume from said liquid perfume reservoir (104) to said spray nozzle (110).
4. The smart perfume emission device (100) of claim 1, wherein said spray nozzle (110) further comprises a variable aperture configured to adjust the spray pattern based on input from said control unit (112).
5. The smart perfume emission device (100) of claim 1, wherein said control unit (112) further includes a wireless communication module configured to transmit fragrance concentration data to an external device for remote monitoring and adjustment.
6. The smart perfume emission device (100) of claim 1, wherein said sensor module (106) is configured to detect the ambient temperature and humidity and transmit said data to said control unit (112) for dynamic adjustment of perfume emission.
7. The smart perfume emission device (100) of claim 1, wherein said actuator unit (108) further comprises a feedback loop that continually adjusts the position of said spray nozzle (110) based on real-time data from said sensor module (106).
8. The smart perfume emission device (100) of claim 1, wherein said liquid perfume reservoir (104) is detachable and comprises a locking unit to secure said reservoir within said housing unit (102) during operation.
9. The smart perfume emission device (100) of claim 1, wherein said spray nozzle (110) further comprises a self-cleaning mechanism configured to prevent clogging due to repeated use of the perfume device.
10. The smart perfume emission device (100) of claim 1, wherein said actuator unit (108) comprises a vibration dampening unit for smooth adjustment of the spray nozzle (110) during operation.




The present disclosure provides a smart perfume emission device (100) that integrates indexing for optimized fragrance control, particularly in portable perfume systems. The device includes a housing unit (102) designed to accommodate a liquid perfume reservoir (104). A sensor module (106) within the housing detects fragrance concentration in the surrounding air. An actuator unit (108), operatively connected to the sensor module, adjusts a spray nozzle (110) based on detected fragrance levels. A control unit (112) regulates the emission of perfume, using real-time data from the sensor module to maintain the desired fragrance intensity. This system enhances fragrance distribution by adapting to environmental conditions.
, Claims:I/We Claims


1. A smart perfume emission device (100) comprising:
a housing unit (102) configured to accommodate a liquid perfume reservoir (104);
a sensor module (106) positioned within said housing unit (102) and configured to detect fragrance concentration in ambient air;
an actuator unit (108) operatively coupled to said sensor module (106) and configured to adjust a spray nozzle (110) positioned at one end of said housing unit (102); and
a control unit (112) connected to said actuator mechanism (108), wherein said control unit (112) regulates perfume emission based on data from said sensor module (106).
2. The smart perfume emission device (100) of claim 1, wherein said sensor module (106) further comprises an air quality sensor configured to measure particulate matter and volatile organic compounds in addition to fragrance concentration.
3. The smart perfume emission device (100) of claim 1, wherein said actuator unit (108) comprises a motorized pump configured to control the flow rate of liquid perfume from said liquid perfume reservoir (104) to said spray nozzle (110).
4. The smart perfume emission device (100) of claim 1, wherein said spray nozzle (110) further comprises a variable aperture configured to adjust the spray pattern based on input from said control unit (112).
5. The smart perfume emission device (100) of claim 1, wherein said control unit (112) further includes a wireless communication module configured to transmit fragrance concentration data to an external device for remote monitoring and adjustment.
6. The smart perfume emission device (100) of claim 1, wherein said sensor module (106) is configured to detect the ambient temperature and humidity and transmit said data to said control unit (112) for dynamic adjustment of perfume emission.
7. The smart perfume emission device (100) of claim 1, wherein said actuator unit (108) further comprises a feedback loop that continually adjusts the position of said spray nozzle (110) based on real-time data from said sensor module (106).
8. The smart perfume emission device (100) of claim 1, wherein said liquid perfume reservoir (104) is detachable and comprises a locking unit to secure said reservoir within said housing unit (102) during operation.
9. The smart perfume emission device (100) of claim 1, wherein said spray nozzle (110) further comprises a self-cleaning mechanism configured to prevent clogging due to repeated use of the perfume device.
10. The smart perfume emission device (100) of claim 1, wherein said actuator unit (108) comprises a vibration dampening unit for smooth adjustment of the spray nozzle (110) during operation.

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