Design and Fabrication of a Smart Monitoring System for Liquefied Petroleum Gas-Operated Cars Based on Global System Mobile

Salman, Tariq M.; Abdullah, Hikmat N.; Marhoon, Hamzah M.; Karam, Zeyad A.

doi:10.3991/ijoe.v19i11.41937

Cited by 2 publications

(1 citation statement)

References 23 publications

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“…2. It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it with an AC -DC adapter or battery to get started [10].…”

Section: A Arduino Microcontrollermentioning

confidence: 99%

Design and Implementation of Arduino-Based Sterilization Robot

Khalaf,

Almukhtar

2023

Control Syst. Optim. Lett.

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In this paper, the primary objective is to design implement a low-cost mobile robot used for the sterilization and control of toxic and flammable gas leaks in the polluted areas. To implement the proposed robot, we employ a tank robot structure equipped with sensors/modules for detection, sterilization, and environmental analysis. The robot is outfitted with a camera to enhance its surveillance capabilities. For sterilization, we utilize ultraviolet rays emitted by a UV Lamp (220V Sterilizer 8W-T5 Tube) in infested areas. Special sensors are strategically placed to identify gases and viruses in the target locations. The sensors include MQ-2 for detecting gases like methane, butane, and smoke, MQ-9 for identifying carbon monoxide and flammable gases, and MQ-135 for continuous measurement of air purity. The UV rays can be remotely activated and deactivated through an infrared control system. Simultaneously, the sensor values (MQ-2, MQ-9, MQ-135) are consistently monitored and transmitted to a central authority responsible for remote surveillance. If any hazardous or toxic gases are detected, the system triggers an alarm, notifying relevant authorities to take prompt action. This integrated approach ensures the efficient sterilization of contaminated areas while actively monitoring and responding to potential gas leaks. The combination of sterilization technology, gas detection sensors, and remote monitoring enhances the safety and effectiveness of the entire system. In the future developments, many approaches can be used such as increasing the controlling area by using Wi-Fi or LoRa and using additional sensors for harmful gas detection.

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“…2. It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it with an AC -DC adapter or battery to get started [10].…”

Section: A Arduino Microcontrollermentioning

confidence: 99%

Design and Implementation of Arduino-Based Sterilization Robot

Khalaf,

Almukhtar

2023

Control Syst. Optim. Lett.

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Smart LPG Leakage Monitoring and Control System Using Gas Sensor (MQ-X), AWS IoT, and ESP Module

Chakraborty,

Aithal

2024

IJAEML

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Purpose: Nowadays, LPG is used in almost every kitchen for cooking. It has lots of advantages over other cooking fuels. We need to maintain compliance when we cook using it. The gas flows through a couple of equipment like a regulator, pipe, knob, and burner. If equipment got damaged or the regulator was kept on after cooking, it emitted the gas. This event is dangerous and destructive. So, once it is emitted, it should be detected immediately, and emissions should be stopped. There are several sensors available to detect the gas. We demonstrate using this sensor to build an intelligent gas monitoring system here. When the gas is detected, we regulate the valve and stop the gas emission using the control mechanism. Design/Methodology: There are two approaches to designing the LPG detector for the researcher. One approach is to create from scratch, using the raw sensor, creating the schematics, and then building the PCB. After that, the components are assembled and tested in a natural environment. Finally, it would be best if we pack within a suitable enclosure. It takes time to make a testable product. The other approach is for rapid prototyping. Here, we followed the fast procedure. To minimize the hardware overhead, we purchased one complete gas detector system, which is available in the market, and then we added our intelligence to it. Findings/Result: We tested the prototype in a natural environment. The result was found as expected and very promising. We inject the LPG into the sensor. After a couple of seconds, the built-in relay got energized. The ESP module sends the message to the predefined mobile number. Originality/Value: Several projects have already been done to detect LPG leakage. Most of the project monitors gas; it produces an alarm if leakage happens. But here we added a couple of facilities. One is when gas leakage is detected instantly; it triggers the close of the regulator valve. The second one is the incident time, which will be uploaded to the cloud, not local device memory. It will help for audit purposes. Once a leak is detected, we can send the message to the What’s App. These features provide value to the user. Type of Paper: Experimental-based Research.

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Design and Fabrication of a Smart Monitoring System for Liquefied Petroleum Gas-Operated Cars Based on Global System Mobile

Cited by 2 publications

References 23 publications

Design and Implementation of Arduino-Based Sterilization Robot

Design and Implementation of Arduino-Based Sterilization Robot

Smart LPG Leakage Monitoring and Control System Using Gas Sensor (MQ-X), AWS IoT, and ESP Module

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