Wireless Sensors and Actuators Distributor for Anti-Pipeline Vandalization Programme Using Iot Philosophy: A Case of Niger Delta Area

Efemena Roseline. Isaac, Chinagolum. Ituma, Chukwuemeka Anyim and Nweso Emmanuel Nwogbaga
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Efemena Roseline. Isaac: Computer Science Department, Ebonyi State University, Abakaliki
Chinagolum. Ituma: Computer Science Department, Ebonyi State University, Abakaliki
Chukwuemeka Anyim: Computer Science Department, Ebonyi State University, Abakaliki
Nweso Emmanuel Nwogbaga: Computer Science Department, Ebonyi State University, Abakaliki

International Journal of Research and Innovation in Applied Science, 2024, vol. 9, issue 9, 1-9

Abstract: The environment in which humans operate is influenced by various factors such as temperature, moisture, light, vibration, humidity, smoke, fire, and even sudden car engine failures. Identifying and understanding these factors, especially in critical areas like crude oil and gas pipelines, is crucial for developing effective intervention strategies. Wireless sensor networks (WSNs) offer a promising solution for detecting and addressing environmental issues. For instance, these systems can identify a fire in a remote area, enabling timely intervention by fire services. As wireless communication technology advances, the ability to design flexible and efficient WSNs for continuous environmental monitoring becomes increasingly feasible. Such networks can monitor, analyze, and control factors like pipeline vandalism in regions like the Niger Delta Area. Unlike traditional wired networks, wireless designs provide greater flexibility in managing these environmental challenges. In this project, a WSN was implemented using the open-source hardware platforms Arduino and Raspberry Pi. The system was designed to be low-cost and highly scalable, making it ideal for environmental monitoring applications. The sensor nodes were designed to be as compact as possible, using 1-wire sensors like the DS18B20 temperature sensor. Unlike analog sensors that rely on analog pins, these digital sensors can be driven by a single digital pin, allowing a single sensor node to support multiple sensors. To ensure continuous operation, the voltage of the battery powering the sensor nodes is also monitored. The system automatically connects new sensor nodes that come within range of the base receiving node, ensuring seamless data tracking from the sensors. Data transmission and reception are facilitated by nRF24L01(+) radio modules, while a user interface provides remote access. An HTTP web server was established at the base station, allowing the received data to be retrieved via a web browser on a PC. The overall system architecture, including detailed hardware and software design, is presented. Example measurement results are provided to demonstrate the system’s effectiveness in environmental monitoring.

Date: 2024
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