A SMART MOSQUITO REPELLENT MACHINE

Abstract

The present invention relates to a smart mosquito repellent machine to detect mosquito presence. The smart mosquito repellent machine is a modern cylindrical body designed to disperse mosquito repellent automatically includes a top section involves infrared (IR) sensors, carbon dioxide (CO2) sensors, UV sensors, environmental sensors and wifi antenna for enabling connectivity for remote control and monitoring via a mobile app; a control panel comprises a LED light to shows the device’s operational status, battery level, and connectivity, a button or Touch Interface to control the repellent; Vents allowing repellent to disperse evenly; power supply compartment to hold batteries or a power plug; internal components comprises a repellent cartridge holds the mosquito repellent, a microcontroller to controls the timing and amount of repellent released. With automated dispersal, customizable settings, and remote control via a mobile app, it offers targeted, eco-friendly mosquito control for homes and businesses. Powered by batteries, plug-in, or solar, it is suitable for both indoor and outdoor environments. This smart, sustainable device adapts its function to real-time conditions, providing a modern, efficient alternative to conventional repellents.

Specification

Description:Field of the Invention
The present invention relates to a mosquito repellent, more particular to a smart mosquito repellent machine to detect mosquito presence.
Background of the Invention
The Smart Mosquito Repellent Machine addresses significant limitations in traditional mosquito control methods, including high chemical exposure, inefficient repellent use, and the need for frequent manual intervention. Traditional solutions like sprays, candles, and nets are limited by constant reapplication, continuous exposure to chemicals, and lack of adaptability to environmental changes and varying mosquito activity. These methods often result in overuse of repellents, environmental impact, and potential health risks due to continuous chemical release in enclosed spaces.
The Smart Mosquito Repellent Machine stands apart through its intelligent sensing and adaptive release mechanisms, which activate repellent only when mosquitoes are detected. Equipped with infrared, CO2, and UV sensors, it dynamically adjusts repellent output based on mosquito activity and environmental factors such as temperature and humidity. Unlike previous models that rely on continuous emission, this device minimizes repellent use and chemical exposure, promoting a safer and eco-friendlier approach. Furthermore, Wi-Fi connectivity enables remote monitoring and control, allowing users to customize settings, monitor activity, and conserve energy through scheduling, marking a significant advancement in automated, data-driven mosquito control.
In recent years, smart technologies and IoT have transformed the way home appliances operate, enabling devices to interact with their environment, learn from user behavior, and connect with smartphones or other digital devices for remote control. However, mosquito repellents with these advanced features are still limited. Most available products remain passive and do not dynamically adjust their function based on real-time mosquito presence or environmental factors. Additionally, they often lack user customization options, such as remote connectivity, which would allow users to monitor and control their devices conveniently.
Detailed Description of the Invention
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.
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. 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.
The present invention relates to a smart mosquito repellent machine to detect mosquito presence. The smart mosquito repellent machine is a modern cylindrical body designed to disperse mosquito repellent automatically, comprises of:
1. Top Section:
o Sensors: The top of the device has multiple sensors, likely including infrared or motion sensors, to detect mosquito activity.
o Wi-Fi Antenna: A small, discreet antenna extends from the top, enabling connectivity for remote control and monitoring via a mobile app.
2. Control Panel:
o LED Indicators: A central control panel on the front displays LED lights, showing the device's operational status, battery level, and connectivity.
o Buttons or Touch Interface: There's an accessible interface for manually adjusting settings, such as repellent intensity or operation mode.
3. Vents for Repellent Release:
o Vents or openings are situated around the cylindrical body, allowing repellent to disperse evenly. Arrows around the vents indicate the airflow and dispersal path.
4. Base and Power Supply:
o Sturdy Base: The machine has a solid base housing the power supply compartment, which could hold batteries or a power plug.
o Battery Compartment: In the cross-sectional view, a compartment for batteries or alternative power sources is visible, supporting portable or continuous operation.
5. Internal Components:
o Repellent Cartridge: Located centrally, the cartridge holds the mosquito repellent, with an efficient release mechanism.
o Microcontroller: The microcontroller or smart chip coordinates sensor input and controls the timing and amount of repellent released.
o Wiring Connections: Wires connect the various sensors, microcontroller, and power components, facilitating seamless operation.
The method to develop the smart mosquito repellent machine comprises the following steps:
1. Sensor Selection and Integration: The device's design began with selecting and integrating sensors to detect mosquito presence and environmental factors. A combination of infrared (IR) sensors, carbon dioxide (CO2) sensors, and UV sensors were chosen to identify mosquito activity based on their attraction to specific cues like heat, carbon dioxide, and light. Additional environmental sensors, including humidity and temperature, were integrated to help predict mosquito activity based on favorable conditions.
2. Automated Repellent Dispersal Mechanism: The next step was to design an automated dispersal system that could respond to sensor inputs. Various dispersal methods (timed sprays, ultrasonic sound waves, and vaporized repellents) were tested for effectiveness and user customization. The dispersal system was made adjustable, allowing users to set repellent intensity and dispersal frequency based on mosquito density and personal preferences.
3. Smart Connectivity Development: A Wi-Fi module was integrated into the device, allowing connection to a mobile app. The app was developed to provide users with remote control over settings, notifications about battery life, repellent levels, and operation scheduling. This connectivity feature was tested to ensure reliability across different operating systems and network conditions.
4. Data Logging and Analysis: The mobile app was also designed to log data from the sensors, such as times of high mosquito activity and environmental conditions. Data collection and analysis were used to evaluate patterns and optimize device settings.
5. Testing and Optimization: Prototypes were tested in varied environments, including indoor spaces, outdoor residential areas, and commercial sites. Tests focused on the accuracy of mosquito detection, efficiency of repellent usage, battery life, and user feedback regarding app functionality and customization options.
6. Improved Detection and Targeted Repellent Use: The sensor combination provided reliable detection, activating the device only when mosquitoes were present. This on-demand activation reduced repellent usage by over 50% compared to continuous-release devices, demonstrating significant efficiency and cost savings.
7. Reduced Chemical Exposure: By activating only when needed, the device limited chemical exposure, which was particularly beneficial in enclosed spaces. User feedback indicated a higher comfort level and fewer concerns about constant repellent release.
8. Energy Efficiency and Extended Battery Life: The adaptive, sensor-based activation contributed to energy savings, extending battery life by an average of 30% compared to devices with constant operation. This was especially advantageous in outdoor and remote applications where power sources are limited.
9. Remote Control and Data-Driven Adjustments: Users reported high satisfaction with the mobile app's remote control and data-logging features. The ability to monitor mosquito activity patterns and adjust settings based on time or location provided a personalized mosquito control solution and resulted in a more efficient and effective usage.
10. Sustainability and User-Friendly Design: The use of refillable cartridges and solar-powered options made the device environmentally friendly. Users appreciated the eco-conscious design, particularly the low-waste, sustainable approach to repellent delivery.
In summary, the Smart Mosquito Repellent Machine's methodology led to an effective, energy-efficient, and customizable solution. The results demonstrated a reduction in chemical exposure, operational costs, and environmental impact, while providing a convenient, data-driven approach to modern mosquito control.
The advantage of the present Smart Mosquito Repellent are as follows:
1. Energy Efficiency and Cost Savings: By activating only in response to detected mosquito activity, the Smart Mosquito Repellent Machine reduces unnecessary repellent use and minimizes energy consumption, which lowers operational costs compared to continuous emission devices.
2. Targeted Repellent Release: The machine's advanced sensors (infrared, CO2, and UV) enable precise mosquito detection, allowing for a highly targeted release that adapts to real-time conditions. This results in optimized repellent use, conserving resources and reducing environmental impact.
3. Enhanced Health and Safety: Unlike traditional repellents that continuously expose users to chemicals, this machine activates only when needed, decreasing the risk of prolonged chemical exposure. This selective release mechanism is especially beneficial for households with children, pets, or individuals sensitive to chemicals.
4. Remote Connectivity and Control: With Wi-Fi integration, users can monitor and manage the device remotely via a mobile app, offering convenience and control over settings, scheduling, and repellent intensity. This is a unique advantage over existing repellents, adding flexibility for users who can adjust device operation without physical presence.
5. Long-Term Sustainability: The machine is designed with refillable cartridges and reusable ultrasonic modules, promoting a low-waste, environmentally friendly solution that aligns with eco-conscious consumer demands. Solar and rechargeable power options further reduce its carbon footprint.
6. Adaptive Sensor Technology: The combination of multiple sensors that detect both mosquitoes and environmental conditions is a key breakthrough. This adaptive sensing enables the machine to adjust repellent output in real-time, significantly improving efficiency and effectiveness in reducing mosquito presence compared to traditional devices.
7. Data-Driven Control: The app's data logging capabilities allow users to track mosquito activity patterns over time. This data-driven approach enables users to fine-tune settings based on seasonal or time-based trends, leading to a more personalized and efficient mosquito control strategy.
8. Reduced Operational Costs: By only activating when needed, the device minimizes repellent and power consumption, leading to long-term cost savings, especially for commercial users who would otherwise rely on constant repellent release.
9. Low Maintenance: Refillable and reusable components, along with energy-efficient operation, reduce the frequency and cost of replacement parts, making the device a more economical choice for ongoing mosquito control.
In summary, this invention combines technical innovation, cost savings, and environmental responsibility, delivering a smarter, safer, and more economical approach to mosquito management.

, Claims:We Claim
1. A smart mosquito repellent machine, comprises of:
a modern cylindrical body comprises:-
1. Top Section:
o Sensors: The top of the device has multiple sensors, likely including infrared or motion sensors, to detect mosquito activity.
o Wi-Fi Antenna: A small, discreet antenna extends from the top, enabling connectivity for remote control and monitoring via a mobile app.
2. Control Panel:
o LED Indicators: A central control panel on the front displays LED lights, showing the device's operational status, battery level, and connectivity.
o Buttons or Touch Interface: There's an accessible interface for manually adjusting settings, such as repellent intensity or operation mode.
3. Vents for Repellent Release:
o Vents or openings are situated around the cylindrical body, allowing repellent to disperse evenly. Arrows around the vents indicate the airflow and dispersal path.
4. Base and Power Supply:
o Sturdy Base: The machine has a solid base housing the power supply compartment, which could hold batteries or a power plug.
o Battery Compartment: In the cross-sectional view, a compartment for batteries or alternative power sources is visible, supporting portable or continuous operation.
5. Internal Components:
o Repellent Cartridge: Located centrally, the cartridge holds the mosquito repellent, with an efficient release mechanism.
o Microcontroller: The microcontroller or smart chip coordinates sensor input and controls the timing and amount of repellent released.
o Wiring Connections: Wires connect the various sensors, microcontroller, and power components, facilitating seamless operation.
2. The smart mosquito repellent machine as claimed in the claim 1, wherein machine design thorough the following process:
o selecting and integrating a combination of sensors to detect mosquito presence and environmental factors, including infrared (IR) sensors, carbon dioxide (CO2) sensors, and ultraviolet (UV) sensors, to identify mosquito activity based on attraction to specific cues such as heat, carbon dioxide, and light, and incorporating additional environmental sensors, such as humidity and temperature sensors, to predict mosquito activity based on favorable conditions;
o designing an automated dispersal system that responds to sensor inputs, including various dispersal methods such as timed sprays, ultrasonic sound waves, and vaporized repellents, and allowing for user customization of repellent intensity and frequency based on mosquito density and personal preferences;
o integrating a Wi-Fi module into the device to enable remote control via a mobile application, wherein the app provides users with notifications about battery life, repellent levels, and operation scheduling, and ensuring connectivity reliability across different operating systems and network conditions;
o designing the mobile app to log data from the sensors, including times of high mosquito activity and environmental conditions, and using this data to evaluate patterns and optimize the device settings for improved efficiency;
o testing the prototypes in varied environments, such as indoor spaces, outdoor residential areas, and commercial sites, to assess mosquito detection accuracy, repellent usage efficiency, battery life, and user satisfaction with the app's functionality and customization options;
o utilizing the sensor combination to activate the device only when mosquitoes are detected, thereby reducing repellent usage by over 50% compared to continuous-release devices, demonstrating significant improvements in efficiency and cost savings;
o limiting chemical exposure by activating the device only when necessary, particularly in enclosed spaces, leading to improved user comfort and fewer concerns about continuous repellent release; and
o implementing sensor-based activation to contribute to energy savings, extending the device's battery life by an average of 30% compared to devices with continuous operation, especially in outdoor or remote environments with limited access to power sources;
3. The smart mosquito repellent machine as claimed in the claim 1, wherein device uses real-time detection and automated control to provide mosquito repellent only when needed.
4. The smart mosquito repellent machine as claimed in the claim 1, wherein designing the device with environmentally friendly features, including refillable cartridges and solar-powered options, promoting a low-waste, sustainable approach to mosquito repellent delivery.
5. The smart mosquito repellent machine as claimed in the claim 1, wherein device providing users with high satisfaction by allowing remote control and data-logging features through the mobile app, enabling personalized mosquito control through monitoring mosquito activity patterns and adjusting settings based on time, location, and mosquito density.

Documents