Smart Trash Collection System – An IoT and Microcontroller-Based Scheme

Paul, Niloy Kanti; Saha, Dipanwita; Biswas, Kaushik; Akter, Samia; Islam, Rifat Tasnia; Bhuyan, Manabendra

doi:10.9734/jerr/2023/v24i11849

Cited by 4 publications

(4 citation statements)

References 7 publications

(7 reference statements)

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“…Microcontroller-based systems are found portable, cost-effective, and efficient for variousapplications like motor control, bio-medical devices, cleaning systems, tracking, control, and protection systems, etc. [7][8][9][10][11][12][13][14]. Microcontrollerbased ultrasonic sound signal was employed in many types of systems including distance measurement applications [12,15].…”

Section: Introductionmentioning

confidence: 99%

“…[7][8][9][10][11][12][13][14]. Microcontrollerbased ultrasonic sound signal was employed in many types of systems including distance measurement applications [12,15]. The ultrasonic sound can be produced using an Arduino microcontroller and can be applied to repel mosquitoes with recent studies indicating frequencies in the range of 18-48 kHz [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

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Design, Testing, Evaluation, and Implementation of an Arduino-based Mosquito-Repellent System

Malik,

Abid,

Rafi

et al. 2024

JERR

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Aims: The primary objective of this research drive is to design, develop, and evaluate an Arduino-based mosquito-repellent system. This work underscores the importance of developing sustainable and eco-friendly solutions for mosquito control. Study Design: An Arduino microcontroller board is used, and an assembly language program is developed to repel mosquitoes from the surroundings. This system uses piezoelectric disks, LED lights, LCD monitor along with the Arduino board and produces ultrasonic sound to protect humans and the environment from mosquitoes. Place and Duration of Study: The research effort was steered by the authors in a group under the supervisor of a faculty member as a part of the course capstone project work of the Bachelor of Science in Engineering degree in Computer Science and Engineering at the American International University Bangladesh (AIUB), Dhaka, Bangladesh. The authors performed their research tasks at AIUB from May 2023 to January 2024. Methodology: The innovative mosquito-repellent system uses an Arduino Mega 2560 microcontroller to generate a cutting-edge solution to tackle the problem of mosquito infestations. The system can produce an electric signal that can emit mechanical ultrasound signals to be harnessed using a series-connected eight piezo-electric discs. To power up the system, it uses four Li-ion rechargeable batteries charged by using solar energy from the home solar system. Besides, it uses LEDs to indicate the status of the repellent system. Results: The generated ultrasonic signal is observed on the oscilloscope screen and its’ value is exhibited on the LCD screen to evaluate the system performance. Testing confirms that the system can drive away mosquitoes within its 3 m surroundings in 2-3 minutes. Besides, the system parameter and cost comparison show that this scheme suggests a worthwhile and sustainable result for making a mosquito-free environment. Conclusion: The development of a mosquito-repellent system using ultrasonic sound waves based on an Arduino microcontroller offers a sustainable and effective alternative to traditional methods of mosquito control. Since the system is chemical and health-hazard-free, it is eco-friendly and makes human life more comfortable. The system is portable and cost-effective, making it suitable for use in various settings.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design, Testing, Evaluation, and Implementation of an Arduino-based Mosquito-Repellent System

Malik,

Abid,

Rafi

et al. 2024

JERR

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“…Therefore, regular cleaning is required to maintain optimal performance and extend the lifespan of solar panels. Thus, this research work proposes an IoT-based and microcontroller-operated automated solar panel cleaning and power monitoring system to address this problem, because IoT is a state-of-art technology for any monitoring system and a microcontroller was found very suitable in many application areas [4][5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

IoT-Based Automated Solar Panel Cleaning and Monitoring Technique

Biswas,

Bhuyan,

Hassan

2023

JERR

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Aims: The objective of this research work is to design and develop an IoT-based automated solar panel cleaning and real-time monitoring system using a microcontroller to improve the output and efficiency of a solar module at a low cost. Study Design: Most of the time, dust over solar panels creates a barrier that obstructs the sun’s radiation and reduces their performance. As such, it is necessary to keep the solar panel clean to improve output power levels. We integrated the IoT technology along with a range of components, including a microcontroller, a NodeMCU, a servo motor, a DC motor-driven submersible pump, a Light Dependent Resistor (LDR), an LCD with driver IC, etc. to design the system. We developed the assembly language program for the microcontroller. Place and Duration of Study: The work was conducted individually under the supervisor of a faculty member as a part of the final project work of the Master of Engineering degree in Electrical and Electronic Engineering at American International University Bangladesh (AIUB), Dhaka, Bangladesh. The student conducted his research work at AIUB for two consecutive semesters from September 2022 to May 2023. Methodology: An LDR sensor detects the solar panel’s dirtiness and triggers the cleaning process through the microcontroller. The system monitors this continuously and real-time vital data is accessible to have some performance metrics, empowering timely maintenance actions to be triggered by the system and hence ensuring the maximum power output. The automated cleaning mechanism, driven by servo motors and mini submersible DC motor pumps, effectively removes dust and dirt from solar panels. An application was used to get real-time data through the internet to the user’s smartphone. Results: The server data is accessed to observe the system performance. The cost analysis shows that this system offers a cost-effective and sustainable solution for maintaining clean solar panels and optimizing power output. Conclusion: Such an automation system can contribute meaningfully to the progression of renewable power generation by significantly improving the efficiency and longevity of solar panels. Thus, we can have sustainable and efficient energy systems in the country by integrating IoT-based automation systems.

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“…Microcontroller can be integrated with various sensors such as temperature and humidity sensors. This technology is popularly applied in various sectors such as industry, transportation, energy [12]. The advantage of this technology is that it is capable of providing real-time measurement results and can reduce conventional methods in order to be more modern and efficient [13].…”

Section: Introductionmentioning

confidence: 99%

Experimental Study of Cooling Performance and Electrical Parameters in a Microcontroller-Driven Inverter AC System

Negara,

Anakottapary,

Midiani

et al. 2023

INVOTEK

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Recent advancements in air conditioning (AC) technologies, such as inverters, enable the compressor to remain activated despite reaching the setpoint temperature. This study investigates the cooling performance and electrical parameters of a split inverter AC system controlled by a microcontroller in order to determine the operational performance characteristics of the air conditioning system. An ATmega 2560 microcontroller integrated with PZEM, DS18B20, and LCD I2C sensors monitors was 8,525 Btu/h capacity split inverter AC. During a 1-hour experimental run, the temperature differential between supply air (Tsupply) and return air (Treturn) stabilized at approximately 17 °C, with Tsupply reaching a minimum of 8.5 °C. Treturn remained relatively constant after 500 s with no fluctuations. Moreover, power draw maintained an average of 750 W (1 PK) with no variations, exhibiting an inverse relationship with Tsupply. The maximum energy consumption recorded during the experiment was 1,373 kWh. As expected based on fundamental thermodynamic principles, the energy usage showed a direct proportional relationship with the total runtime of the system. That is, the longer the AC system was engaged, the higher the total energy required to maintain the cooling effect. Overall, microcontroller-based split inverter AC enables real-time performance monitoring and efficient operation, representing a promising technology.

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Smart Trash Collection System – An IoT and Microcontroller-Based Scheme

Cited by 4 publications

References 7 publications

Design, Testing, Evaluation, and Implementation of an Arduino-based Mosquito-Repellent System

Design, Testing, Evaluation, and Implementation of an Arduino-based Mosquito-Repellent System

IoT-Based Automated Solar Panel Cleaning and Monitoring Technique

Experimental Study of Cooling Performance and Electrical Parameters in a Microcontroller-Driven Inverter AC System

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