Description:FIELD OF THE INVENTION

[0001] The present invention relates to an integrated conditioned airflow distribution system that is capable of delivering controlled airflow and ambient fragrance, adapting to environmental conditions, and enhancing comfort and air quality within indoor spaces.

BACKGROUND OF THE INVENTION

[0002] Indoor environments such as offices, homes, commercial spaces, and public areas require effective management of airflow, air quality, and ambient conditions to maintain comfort and wellbeing. Existing solutions often focus solely on ventilation or temperature control, while neglecting additional sensory factors such as fragrance or adaptive lighting. Manual adjustments are frequently necessary to achieve desired environmental conditions, which lead to inefficiency, uneven comfort, and increased energy consumption. There is a growing need for systems that intelligently monitor environmental parameters in real-time and respond dynamically to changes, providing consistent comfort, improved air quality, and enhanced user experience.

[0003] Traditionally, indoor climate control relies on fixed-position fans, static HVAC units, or manually operated systems that operate at predetermined speeds and orientations. Fragrance distribution, when available, is generally passive or manually controlled, leading to uneven coverage and limited effectiveness. These conventional systems lack real-time sensing and automated decision-making, requiring continuous human intervention to maintain comfort. As a result, energy efficiency is reduced, environmental conditions fluctuate, and user satisfaction is compromised.

[0004] US20020124992A1 discloses a system and method for cooling and heating of buildings consisting of an integrated assembly of devices, including a variable speed air handler, hot water heating coil, outside air damper, controller, and optional compressor-based air conditioner. During summer the system utilizes nighttime outside air for cooling and uses air temperature predictions to provide information about optimal control settings and to maintain comfort. During winter the system varies airflow with heating demand and ventilates with outside air to maintain indoor air quality.

[0005] US7302313B2 discloses an air monitoring system is disclosed having an air monitoring unit with at least one sensor for measuring data of an air quality parameter and a computer for storing the air quality parameter data received from the sensor. The air monitoring unit may use an installed or a portable system, or a combination of both, for measuring the air quality parameters of interest. A remote data centre may be provided, and the data may be uploaded to the data centre from the unit by a communications media such as the Internet. Information or instructions may also be downloaded from the data centre to the unit via the communications media for controlling or modifying the function of the unit. An expert system may be provided with the air monitoring system for controlling the unit. The information or instructions downloaded to the unit may be generated by the expert system.

[0006] Conventionally, many systems for indoor airflow and environmental control rely on fixed fans, static HVAC units, or manual systems, providing limited adaptability to changing conditions. Additionally, these existing systems often require frequent human intervention to maintain comfort, resulting in inconsistent airflow, uneven air quality, and inefficient energy usage in indoor spaces.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a system that requires to intelligently monitor environmental conditions in real time, dynamically adjust airflow, fragrance distribution, and illumination, and provide automated, adaptive control to maintain consistent comfort, improved air quality, and energy-efficient operation in indoor spaces.

OBJECTS OF THE INVENTION

[0008] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0009] An object of the present invention is to develop a system that provides controlled and adjustable airflow to enhance indoor comfort and maintain optimal environmental conditions.

[0010] Another object of the present invention is to develop a system that disperses ambient fragrances uniformly to improve sensory experience and create a pleasant indoor atmosphere.

[0011] Another object of the present invention is to develop a system that dynamically adapts to changes in occupancy, environmental conditions, and lighting levels, ensuring energy-efficient operation and consistent comfort.

[0012] Yet another object of the present invention is to develop a system that enables remote monitoring and control, allowing users to manage indoor conditions conveniently and effectively.

[0013] The foregoing and other objects, features, and advantages of the present invention will become readily apparent upon further review of the following detailed description of the preferred embodiment as illustrated in the accompanying drawings.

SUMMARY OF THE INVENTION

[0014] The present invention relates to an integrated conditioned airflow distribution system that is capable of providing adaptive airflow, enhancing indoor air quality, maintaining user comfort, dispersing ambient fragrances uniformly, responding to environmental changes, and dynamically adjusting illumination for an optimized indoor experience.

[0015] According to an aspect of the present invention, an integrated conditioned airflow distribution system, comprises of a base slidably mountable with a surface by means of a sliding arrangement, an enclosure installed underneath the base by means of a telescopic rod, to house electrical components of the system, a housing mounted removably with a fan unit installed underneath the housing, the fan unit comprising a bar with central hub and a plurality of blades attached radially with the hub to displace air by rotation, a vibration damper installed with the base to absorb vibrations, the bar is attached with the enclosure by means of fasteners coupled with a hook provided in the enclosure, a fragrance unit is installed in the housing to disperse fragrance into the air flow via an outlet nozzle, the fragrance unit comprises a plurality of sections stored within the housing, each stored with a fragrance, a mixing chamber connected with the sections to receive plurality of the fragrances for mixing, a nebulizer pump connected with the chamber, to disperse the fragrance into a venturi unit installed with the outlet nozzle, a dispersal arrangement installed with the fan unit to disperse the fragrance uniformly in the airflow, an LDR (light dependent resistor) embedded on the housing to detect an ambient light level, to trigger a plurality of LEDs (light emitting diodes) mounted on the housing to provide illumination if the detected ambient light level is below a threshold light level.

[0016] According to another aspect of the present invention, the system further comprises of a spout provided at an end of each of the tubes to dispense the fragrance received from the fragrance unit, a sensing unit installed with the enclosure to detect an ambient occupancy level, temperature a CO2 concentration and air quality, the sensing unit comprises an imaging unit to detect occupancy levels by capturing images in vicinity of the fan unit, a temperature sensor to detect ambient temperature, a gas sensor to detect CO2 concentration and a PM (particulate matter) sensor to detect air quality, the sensing unit further comprises a PIR (passive infrared sensor) to detect presence and absence of occupants for an automated switching on and off of the fan unit accordingly, a decision module configured with a control unit provided in the enclosure to receive the data from the sensing unit to determine an ideal position of the fan unit, and quantity of the fragrance to be dispensed to actuate the sliding arrangement, the telescopic rod to accordingly position the fan unit and the fragrance unit to dispense fragrance accordingly, a user interface adapted to be installed with a computing unit for wireless monitoring and operation, by means of a communication unit installed in the housing to enable wireless connection with the user interface.

[0017] While the invention has been described and shown with particular reference to the preferred embodiment, it will be apparent that variations might be possible that would fall within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
Figure 1 illustrates an isometric view of an integrated conditioned airflow distribution system.

DETAILED DESCRIPTION OF THE INVENTION

[0019] The following description includes the preferred best mode of one embodiment of the present invention. It will be clear from this description of the invention that the invention is not limited to these illustrated embodiments but that the invention also includes a variety of modifications and embodiments thereto. Therefore, the present description should be seen as illustrative and not limiting. While the invention is susceptible to various modifications and alternative constructions, it should be understood, that there is no intention to limit the invention to the specific form disclosed, but, on the contrary, the invention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention as defined in the claims.

[0020] In any embodiment described herein, the open-ended terms "comprising," "comprises,” and the like (which are synonymous with "including," "having” and "characterized by") may be replaced by the respective partially closed phrases "consisting essentially of," consists essentially of," and the like or the respective closed phrases "consisting of," "consists of, the like.

[0021] As used herein, the singular forms “a,” “an,” and “the” designate both the singular and the plural, unless expressly stated to designate the singular only.

[0022] The present invention relates to an integrated conditioned airflow distribution system that is capable of providing a controlled and adjustable flow of air within an indoor environment, maintaining comfort and freshness, enhancing ambient conditions, and responding dynamically to environmental and occupancy variations to ensure optimized airflow, fragrance dispersion, and illumination.

[0023] Referring to Figure 1, an isometric view of an integrated conditioned airflow distribution system is illustrated, comprising a base 101 slidably mounted with a surface by means of a sliding arrangement 102 which comprises a track 103 and a plurality of motorized omnidirectional rollers 104, an enclosure 105 installed underneath of the base 101 by means of a telescopic rod 106, a housing 107 mounted removably with a fan unit 108 installed underneath the housing 107, The fan unit 108 comprising a bar 108a with central hub 108b and a plurality of blades 108c attached radially with the hub 108b, the bar 108a attached with the enclosure 105 by means of fasteners coupled with a hook 109, a plurality of sections 110 stored within the housing 107, a mixing chamber 111 connected with the sections 110, an outlet nozzle 112 installed on the housing 107.

[0024] Figure 1 further illustrates a tube 113 attached over each of the blades 108c by means of a spring loaded clip 114, the tube 113 connected with the nozzle 112 by means of a rotary joint 115, the rotary joint 115 comprises a hollow inner ring 115a mounted over the bar 108a connected with the nozzle 112, a hollow outer ring 115b slidably installed over the inner ring 115a in fluid communication, a spout unit 116 provided at an end of each of the tubes 113, an imaging unit 117 installed with the enclosure 105, a plurality of LEDs (light emitting diodes) 118 mounted on the housing 107.

[0025] The system disclosed herein comprises of a base 101 slidably mounted with a surface by means of a sliding arrangement 102. The base 101 is a robust structural platform designed to provide stable support to the system, typically manufactured from durable materials such as stainless steel or reinforced polymer. The base 101 is engineered with high load-bearing capacity, resistant to wear and corrosion, and configured to withstand operational vibrations while ensuring long-term durability and balance.

[0026] The sliding arrangement 102 operates through a track 103 integrated with motorised omnidirectional rollers 104 integrated along inner lateral surfaces of the track 103 to facilitate a sliding of the base 101 held between the roller 104, each roller 104 driven by miniature electric motors. When a control unit associated with the system issues an activation signal, the motors rotate in coordinated directions, enabling smooth, multidirectional movement of the base 101 along the track 103. Sensors within the arrangement 102 relay positional feedback to the control unit, allowing precise adjustments. This controlled actuation ensures the system relocated seamlessly to an ideal position, with minimal friction and stable alignment during operation.

[0027] The track 103 is constructed with inner lateral surfaces designed to house motorized omnidirectional rollers 104, each roller 104 comprising multiple smaller free-rotating wheels mounted around a central hub 108b at specific angles. When actuated by the control unit, the hub-driven motors rotate the rollers 104, and the angled peripheral wheels generate thrust in both longitudinal and lateral directions. This unique geometry allows the base 101 to glide smoothly across the track 103 in any direction. The control unit regulates roller 104 speed and orientation, enabling precise, multidirectional movement with minimal mechanical resistance.

[0028] An enclosure 105 installed underneath the base 101 by means of a telescopic rod 106 house electrical component of the system. The enclosure 105 is a protective casing designed to shield sensitive parts of the system from dust, moisture, and mechanical stress. The enclosure 105 is typically fabricated from lightweight, heat-resistant materials such as aluminium alloy or engineered polymer, incorporating ventilation slots and sealing features to maintain durability, structural integrity, and controlled internal conditions.

[0029] The telescopic rod 106 consists of nested cylindrical segments that extend and retract smoothly within one another. When actuated by the control unit, a pneumatic unit connected to the rod 106 directs compressed air into designated chambers, generating pressure that forces the inner segments to slide outward, thereby elongating the rod 106. For retraction, air is vented or redirected, allowing the segments to collapse back under controlled force. Integrated seals and guides prevent air leakage and ensure stability during motion. The control unit regulates air flow, enabling precise vertical positioning.

[0030] A housing 107 mounted removably with a fan unit 108 installed underneath the housing 107. The housing 107 is a modular shell designed to accommodate and protect functional assemblies, built from lightweight, durable materials such as ABS plastic or aluminium. The housing 107 incorporates aerodynamic contours to guide airflow, and internal mounting slots for secure component placement.

[0031] The fan unit 108 comprising a bar 108a with central hub 108b and a plurality of blades 108c attached radially with the hub 108b to displace air by rotation. The bar 108a with central hub 108b functions as the core structural member of the fan unit 108. The hub 108b is precision-engineered to house a bearing assembly, allowing smooth rotation around its axis. The hub 108b securely connects to the driving shaft, transmitting torque efficiently to the bar 108a. The bar 108a is fabricated from lightweight yet rigid material such as aluminium alloy, ensuring minimal vibration during rotation. The hub’s geometry is optimized to balance centrifugal forces, providing a stable platform for mounting multiple blades 108c radially.

[0032] When actuated by the control unit, the plurality of blades 108c operates by converting rotational energy from the hub 108b into directed airflow. Each blade 108c is aerodynamically contoured with a specific pitch angle to create a pressure difference between its upper and lower surfaces, generating lift and displacing air forward. The blades 108c are generally manufactured from composite or polymeric materials to balance strength with low weight, reducing rotational inertia. Internal reinforcement ribs within the blades 108c enhance rigidity, ensuring consistent airflow and efficient performance during high-speed operation.

[0033] Further, the bar 108a is attached with the enclosure 105 by means of fasteners coupled with a hook 109 provided in the enclosure 105. The fasteners are precision-threaded elements designed to securely join the bar 108a with the enclosure’s hook 109, providing firm yet detachable engagement. Internally, they distribute clamping force evenly to prevent loosening under vibration. The hook 109 is an integrated anchoring feature shaped to interlock with the fasteners, guiding their alignment during installation. When tightened, the fasteners compress against the hook’s surface, creating a mechanical lock that resists displacement. This cooperative means ensures stable attachment while allowing disassembly for maintenance or component replacement without damaging the structure.

[0034] A fragrance unit installed in the housing 107 to disperse fragrance into the air flow via an outlet nozzle 112. The fragrance unit comprises of a plurality of sections 110 stored within the housing 107 to store fragrance in each of the sections 110. The plurality of sections 110 functions as individual storage compartments, each designed to hold a distinct fragrance. Constructed from non-reactive, airtight materials, they prevent contamination or evaporation. Internal partitions isolate the fragrances, while outlet channels allow controlled release.

[0035] A mixing chamber 111 connected with the sections 110 to receive plurality of the fragrances for mixing. The mixing chamber 111 operates as a controlled environment where fragrances from multiple sections 110 converge for uniform blending. Internally, the chamber 111 is shaped with smooth, curved walls to minimize turbulence and prevent residue buildup. Inlets from each section 110 are equipped with valves, allowing precise regulation of fragrance flow into the chamber 111. Once inside, the chamber 111 employs diffuser plates to evenly distribute and homogenize the incoming streams.

[0036] The mixed fragrance is then directed toward a nebulizer pump connected with the chamber 111 to disperse the fragrance into a venturi unit installed with the outlet nozzle 112. The nebulizer pump works by converting liquid fragrance into a fine mist for effective dispersion. Internally, the pump uses a diaphragm actuated by a miniature motor to generate pulsating pressure. This pressure forces the liquid through a narrow orifice at high velocity, breaking the liquid into microscopic droplets. A capillary feed ensures consistent liquid supply, while non-return valves prevent backflow. The result is a stable, fine aerosol that enhances mixing with air, preparing the fragrance for efficient delivery through the connected venturi unit.

[0037] The venturi unit installed with the outlet nozzle 112 operates on the principle of pressure differential. As air passes through the narrow throat of the venturi, its velocity increases while static pressure decreases, creating a suction effect. This low-pressure zone draws in the nebulized fragrance mist from the pump, entraining it into the high-speed airflow. The internal geometry is precisely designed to optimize mixing, ensuring uniform fragrance distribution through the outlet nozzle 112 without clogging or backflow.

[0038] The nozzle 112 functions as the final dispensing element that releases the fragrance-air mixture into the environment. Internally, the nozzle 112 is engineered with a tapered converging-diverging geometry to accelerate the flow while maintaining laminar conditions. A fine mesh incorporated to further break down residual droplets, ensuring a consistent mist. The internal surfaces are polished to minimize adhesion and clogging, while adjustable outlets allow controlled spray angle and coverage. This design ensures efficient, uniform fragrance dispersion.

[0039] A dispersal arrangement installed with the fan unit 108 to disperse the fragrance uniformly in the airflow. The dispersal arrangement comprises a tube 113 attached over each of the blades 108c by means of a spring-loaded clip 114. The tubes 113 function as flexible conduits designed to transport the fragrance mist from the nozzle 112 to the dispersal points on the blades 108c. Internally, they are constructed from lightweight, non-reactive polymers with smooth bores to minimize resistance and condensation. Their flexibility ensures reliable flow even under continuous rotation.

[0040] The spring-loaded clip 114 consists of two opposing jaws connected by a pivot and an integrated coiled or leaf spring. When external force is applied to open the jaws, the spring compresses or flexes, storing potential energy. Upon release, this stored energy drives the jaws back together, exerting uniform clamping pressure on the surface beneath. The inner gripping faces feature textured ridges or pads to enhance friction and prevent slippage. This ensures the tube 113 remains firmly attached during rotation and vibration.

[0041] The tube 113 further connected with the nozzle 112 by means of a rotary joint 115 enabling rotation of the tubes 113 with the blades 108c while allowing a fluid communication with the nozzle 112. The rotary joint 115 comprises a hollow inner ring 115a mounted over the bar 108a, connected with the nozzle 112 to receive the fragrance. A hollow outer ring 115b slidably installed over the inner ring 115a in fluid communication with the inner ring 115a, the tubes 113 connected with holes provided with outer surface of the outer ring 115b.

[0042] The rotary joint 115 operates by maintaining continuous fluid communication between stationary and rotating components. The hollow inner ring 115a channels fragrance from the nozzle 112 into its cavity. Surrounding inner ring 115a, the hollow outer ring 115b is slidably mounted, allowing free rotation while remaining sealed against the inner ring 115a via gaskets. Fragrance flows from the inner ring 115a into the outer ring’s cavity and exits through precision-drilled holes along its surface, which connect to the tubes 113. This design enables uninterrupted fluid transfer during blade 108c rotation.

[0043] Furthermore, a spout unit 116 provided at an end of each of the tubes 113 to dispense the fragrance received from the fragrance unit. The spout unit 116 functions as a precision dispensing outlet that releases fragrance mist into the airflow when actuated by the control unit. Internally, the spout unit 116 incorporates a micro-valve means, typically solenoid-driven, which opens upon receiving an electrical signal. This valve regulates the flow of mist from the connected tube 113, ensuring controlled release without leakage. A narrowing channel within the spout unit 116 accelerates the mist, maintaining a fine spray pattern. Once the control signal stops, the valve closes instantly, preventing drips and ensuring efficient, on-demand operation.

[0044] A sensing unit installed with the enclosure 105 to detect an ambient occupancy level, temperature of CO2 concentration and air quality. The sensing unit comprises an imaging unit 117 to detect occupancy levels by capturing images in vicinity of the fan unit 108, a temperature sensor to detect ambient temperature, a gas sensor to detect CO2 concentration and a PM (particulate matter) sensor to detect air quality.

[0045] The imaging unit 117 operates using a digital camera module integrated with a lens to capture visual data of the surrounding area. Light enters through the lens and is focused onto an image sensor that is CMOS (Complementary Metal-Oxide-Semiconductor) array, which converts photons into electrical signals. These signals are processed by an onboard image processor that extracts occupancy-related information, such as movement or count of individuals. The processed data is then transmitted to the control unit for analysis and automated system adjustments.

[0046] The temperature sensor operates by detecting thermal variations in the surrounding environment and converting them into electrical signals. Commonly, a thermistor-based element changes resistance in response to temperature fluctuations. This signal is amplified and transmitted to the control unit, which interprets the data to monitor ambient conditions. The control unit then trigger system responses, such as adjusting fan speed or activating climate-related functions, ensuring the system maintains optimal environmental conditions in real time.

[0047] The gas sensor detects the concentration of specific gases, such as CO2, by utilizing a sensing element that changes its electrical properties, resistance, current, or voltage, when exposed to the target gas. The sensor continuously sends these signals to the control unit, which analyses the data to determine air quality levels. Based on the readings, the control unit then actuate ventilation, fragrance distribution, or alert means, maintaining safe and comfortable conditions in the environment.

[0048] While, the PM (particulate matter) sensor operates by detecting airborne particles through laser scattering methods. A light source illuminates particles passing through the sensing chamber, and a photodetector measures the scattered light intensity. The sensor converts these measurements into electrical signals corresponding to particle concentration and size. These signals are processed by the control unit, which evaluates air quality and triggers appropriate system responses, such as adjusting airflow or issuing alerts, ensuring the environment remains free of harmful particulate matter.

[0049] The sensing unit further comprises of a PIR (passive infrared sensor) to detect presence and absence of occupants for an automated switching on and off the fan unit 108 accordingly. The PIR (passive infrared) sensor detects the presence of occupants by sensing changes in infrared radiation emitted by warm bodies. Internally, the PIR sensor contains a pyroelectric sensing element that generates electrical signals when exposed to varying IR levels. A Fresnel lens focuses the infrared radiation onto the sensor, enhancing sensitivity and coverage. These signals are amplified and filtered before being sent to the control unit, which interprets the data to determine occupancy and automatically switch the fan unit 108 or other system functions on or off.

[0050] A decision module configured with the control unit provided in the enclosure 105 to receive the data from the sensing unit to determine an ideal position of the fan unit 108, and quantity of the fragrance to be dispensed to actuate the sliding arrangement 102, the telescopic rod 106 to accordingly position the fan unit 108 and the fragrance unit to dispense fragrance accordingly. The decision module internally processes real-time data from the sensing unit, including occupancy, temperature, CO₂, and air quality levels. The decision module uses embedded protocols within the control unit to calculate the optimal fan unit 108 position and determine the precise quantity of fragrance to dispense. Based on these calculations, the decision module generates actuation signals for the sliding arrangement 102 and telescopic rod 106, dynamically adjusting the fan and fragrance unit. Continuous feedback ensures responsive operation, adapting to changes in environmental conditions and occupancy for efficient airflow and fragrance distribution.

[0051] The decision module also blends fragrances from the sections 110 in the chamber 111 as per user input via a user interface and instant weather conditions fetched from a weather module configured with the control unit. The user interface adapted to be installed with a computing unit for wireless monitoring and operation. The user interface functions as an interactive platform allowing the user to monitor and control the system remotely. Internally, the user interface comprises input modules (touchscreen, buttons, or virtual controls) and output modules (display indicators, alerts). Signals from user interactions are transmitted wirelessly via the communication unit to the control unit. The interface also receives status updates and alerts generated by the alert unit, displaying fragrance levels, occupancy data, or system notifications, enabling real-time user oversight and responsive adjustments to system operation.

[0052] The computing unit operates as the central processing hub for the user interface and alert functionalities. Internally, the computing unit comprises a microprocessor, memory modules, wireless communication circuits, and input/output interfaces. The computing unit processes commands from the user interface, interprets system alerts, and relays control signals to the control unit. Simultaneously, the user interface stores historical data, logs system events, and manages wireless connectivity, ensuring seamless communication between the user, the alert unit, and the decision module for efficient monitoring and system management.

[0053] Further, a communication unit installed in the housing 107 to enable wireless connection with the user interface. The communication unit functions as the system’s wireless data transmitter and receiver, enabling interaction between the user interface, control unit, and computing unit. Internally, the communication unit comprises transceivers, antennas, modulation/demodulation circuits, and protocol controllers supporting Wi-Fi, Bluetooth, or other wireless standards. Data packets containing commands, sensor readings, or alerts are encoded, transmitted, received, and decoded within the unit. The control unit coordinates timing and error correction, ensuring reliable, low-latency communication for real-time monitoring, remote operation, and synchronization of system components.

[0054] The weather module functions as an external data integration system for the control unit, providing real-time environmental information. Internally, the weather module comprises a wireless data receiver, signal processor, and memory for temporary storage. The weather module connects to online weather services or local sensors to obtain parameters such as temperature, humidity, wind speed, and atmospheric pressure. The control unit interprets this data to adjust fan positioning, fragrance quantity, and airflow patterns. Continuous updates ensure the system dynamically adapts to changing weather conditions for optimal performance.

[0055] Additionally, an LDR (light dependent resistor) integrated on the housing 107 to detect an ambient light level. The LDR works by changing its electrical resistance in response to ambient light intensity. Internally, the LDR contains a photosensitive semiconductor material that absorbs photons, generating electron-hole pairs that reduce resistance as light increases. This variable resistance is converted into a voltage signal, which is fed to the control unit. The control unit continuously monitors the LDR output and determines if the ambient light level falls below a predefined threshold.

[0056] In case the ambient light level falls below the threshold level, the control unit then activates a plurality of LEDs (Light Emitting Diodes) 118 mounted on the housing 107 to provide illumination. The plurality of LEDs 118 operates as an array of solid-state light emitters, activated by the control unit. Internally, each LED 118 contains a semiconductor junction that emits photons when forward-biased by electrical current. The control unit regulates current and voltage to control brightness and timing. Heat sinks or thermal management layers dissipate excess heat to ensure efficiency and longevity. When triggered by the LDR or user input, the LEDs 118 illuminate uniformly, providing controlled ambient lighting without affecting airflow or fragrance dispersal.

[0057] Lastly, a vibration damper installed with the base 101 to absorb vibrations. The vibration damper functions to absorb and minimize mechanical oscillations transmitted to the base 101. Internally, the vibration damper comprises elastomeric elements coupled with damping fluids that convert kinetic energy into heat, reducing vibrations. Sensors within the damper monitor oscillation levels and transmit signals to the control unit. Upon detecting excessive vibration, the control unit modulates system operations, ensuring stabilized motion, protecting structural components, and maintaining smooth operation of the fan and fragrance dispersal units.

[0058] The present invention works best in the following manner, where the base 101 provides the stable platform supporting the entire system, and the sliding arrangement 102 actuated by the control unit enables precise movement of the base 101 along the track 103 to reach the ideal location. The enclosure 105 houses the control unit and electronic components in the protected environment, while the telescopic rod 106 adjusts the vertical position of the fan unit 108 and fragrance unit as determined by the control unit. The housing 107 secures the fan unit 108, where the central hub 108b rotates smoothly to drive the plurality of blades 108c radially mounted with the hub 108b for efficient air displacement. The fasteners coupled with the hook 109 attach the bar 108a firmly to the enclosure 105, maintaining stability during operation. Fragrance stored in the plurality of sections 110 flows into the mixing chamber 111, where the fragrance is homogenized before being pressurized by the nebulizer pump. The resulting mist is drawn into the venturi unit and distributed through the outlet nozzle 112 on the tubes 113, which are attached to the blades 108c via the spring-loaded clips 114, exiting uniformly through the spout units 116 to ensure even fragrance dispersion. The sensing unit continuously monitors occupancy, ambient temperature, CO2 concentration, air quality, and light levels through imaging, temperature, gas, PM, PIR, and LDR sensors, providing real-time data to the control unit. The decision module processes this information along with environmental inputs from the weather module to determine optimal fan position, fragrance quantity, and activation of the sliding arrangement 102 and telescopic rod 106. When ambient light falls below a threshold, the control unit activates the plurality of LEDs 118 for illumination. The vibration damper stabilizes the base 101 during operation, minimizing oscillations and maintaining system balance. Alerts related to fragrance levels, occupancy, and system performance are transmitted via the communication unit to the computing unit and user interface, enabling wireless monitoring and control.

[0059] Although the field of the invention has been described herein with limited reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternate embodiments of the invention, will become apparent to persons skilled in the art upon reference to the description of the invention. , Claims:1) An integrated conditioned airflow distribution system, comprising:

i) a base 101 slidably mountable with a surface by means of a sliding arrangement 102;
ii) an enclosure 105 installed underneath the base 101 by means of a telescopic rod 106, to house electrical components of the system;
iii) a housing 107 mounted removably with a fan unit 108 installed underneath the housing 107, the fan unit 108 comprising a bar 108a with central hub 108b and a plurality of blades 108c attached radially with the hub 108b to displace air by rotation;
iv) a fragrance unit is installed in the housing 107 to disperse fragrance into the air flow via an outlet nozzle 112;
v) a dispersal arrangement installed with the fan unit 108 to disperse the fragrance uniformly in the airflow;
vi) a spout unit 116 provided at an end of each of the tubes 113 to dispense the fragrance received from the fragrance unit;
vii) a sensing unit installed with the enclosure 105 to detect an ambient occupancy level, temperature a CO2 concentration and air quality;
viii) a decision module configured with a control unit provided in the enclosure 105 to receive the data from the sensing unit to determine an ideal position of the fan unit 108, and quantity of the fragrance to be dispensed to actuate the sliding arrangement 102, the telescopic rod 106 to accordingly position the fan unit 108 and the fragrance unit to dispense fragrance accordingly; and
ix) an LDR (light dependent resistor) embedded on the housing 107 to detect an ambient light level, to trigger a plurality of LEDs (light emitting diodes) 118 mounted on the housing 107 to provide illumination if the detected ambient light level is below a threshold light level.

2) The system as claimed in claim 1, wherein the sliding arrangement 102 comprises a track 103, a plurality of motorised omnidirectional rollers 104 integrated along inner lateral surfaces of the track 103 to facilitate a sliding of the base 101 held between the rollers 104.

3) The system as claimed in claim 1, further comprising a vibration damper installed with the base 101 to absorb vibrations.

4) The system as claimed in claim 1, wherein the bar 108a is attached with the enclosure 105 by means of fasteners coupled with a hook 109 provided in the enclosure 105.

5) The system as claimed in claim 1, wherein the fragrance unit comprises a plurality of sections 110 stored within the housing 107, each stored with a fragrance, a mixing chamber 111 connected with the sections 110 to receive plurality of the fragrances for mixing, a nebulizer pump connected with the chamber 111, to disperse the fragrance into a venturi unit installed with the outlet nozzle 112.

6) The system as claimed in claim 1, wherein the dispersal arrangement comprises a tube 113 attached over each of the blades 108c by means of a spring-loaded clip 114, the tube 113 connected with the nozzle 112 by means of a rotary joint 115 enabling rotation of the tubes 113 with the blades 108c while allowing a fluid communication with the nozzle 112.

7) The system as claimed in claim 6, wherein the rotary joint 115 comprises a hollow inner ring 115a mounted over the bar 108a, connected with the nozzle 112 to receive the fragrance, a hollow outer ring 115b slidably installed over the inner ring 115a in fluid communication with the inner ring 115a, the tubes 113 connected with holes provided along outer surface of the outer ring 115b.

8) The system as claimed in claim 1, wherein the sensing unit comprises an imaging unit 117 to detect occupancy levels by capturing images in vicinity of the fan unit 108, a temperature sensor to detect ambient temperature, a gas sensor to detect CO2 concentration and a PM (particulate matter) sensor to detect air quality.

9) The system as claimed in claim 1, wherein the sensing unit further comprises a PIR (passive infrared sensor) to detect presence and absence of occupants for an automated switching on and off of the fan unit 108 accordingly.

10) The system as claimed in claim 1, wherein the alert unit comprises a user interface adapted to be installed with a computing unit for wireless monitoring and operation, by means of a communication unit installed in the housing 107 to enable wireless connection with the user interface.