A Gas Sensor for Application as a Propane Leak Detector

Bonilla, José Trinidad Guillen; Guillén-Bonilla, Héctor; Rodríguez-Betancourtt, Verónica María; Bonilla, Alex Guillen; Zamora, Antonio Casillas; Blanco, O.; Ramírez-Ortega, Jorge Alberto

doi:10.1155/2021/8871166

Cited by 8 publications

(11 citation statements)

References 37 publications

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“…Therefore, we consider that the ZnAl 2 O 4 is a strong candidate to be applied as a sensor of toxic gases, mainly propane. Comparing the results in Figure 2 with those reported in the references [9,15,23], we found that our sensor ZnAl 2 O 4 had better sensitivity, excellent dynamic response, good reproducibility, shorter response and recovery times at 250 • C. In addition, the curves obtained from the experiments performed at 1000-ppm propane concentrations (see Figure 2), were consistent with those reported in reference [1].…”

Section: Analysis Of the Dynamic Response Of The Znal 2 Osupporting

confidence: 89%

“…That was repeated on several occasions (cycles), which indicated that the pellets maintained a stable process of reversibility and stability in air-propane atmospheres [1]. The excellent response of the ZnAl 2 O 4 was attributed mainly to the reaction that took place on the pellets' surface between the oxygen and the test gas because of the operating temperature (250 • C) [15,23,24]. The temperature provoked the activation of the charge carriers (electrons) [1], making them move faster on the sensor's surface [23,25], causing an almost immediate change in electrical resistance and an increase in the sensitivity of the pellets [1].…”

Section: Analysis Of the Dynamic Response Of The Znal 2 Omentioning

confidence: 96%

“…Some reports have stated that the ZnAl 2 O 4 possesses high sensitivity, good linearity, small hysteresis, and short response and recovery times in humid [9] and propane [1] atmospheres, which is attributed to the porosity and the nanostructures (such as nanorods) obtained during the compound's synthesis [9]. The goal now is to apply new materials (such as the semiconductors) to toxic gas detection systems [15][16][17]. These devices are intended to provide safe zones for humans in C 3 H 8 , CO, or CO 2 atmospheres, among others [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

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Electrical Response of the Spinel ZnAl2O4 and Its Application in the Detection of Propane Gas

Guillén-Bonilla

Bonilla

Rodríguez-Betancourtt

et al. 2021

Applied Sciences

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Nanoparticles of the semiconductor ZnAl2O4 were prepared using a microwave-assisted wet chemistry method in the presence of ethylenediamine and calcination at 250 °C. The material’s crystallinity and purity were verified by X-ray diffraction. The pure phase of the ZnAl2O4 presented a cubic crystalline structure with cell parameters a = 8.087 Å and space group Fd-3m (227). Dynamic tests in propane atmospheres were carried out on pellets (~500 µm in diameter) manufactured with ZnAl2O4 powders. In the tests, the oxide showed variations with time in electrical resistance when injecting air-propane at an operating temperature of 250 °C. The pellets showed good stability, high sensitivity, and an optimal dynamic response as a function of time. On the other hand, a mathematical model was proposed to describe the chemical sensor’s dynamic behavior based on the electrical response and linear systems theory. The sensor’s transient response was obtained with the model by exposing the oxide to air and propane gas; its stability was checked, and the stabilization time was calculated. Subsequently, an operating point was selected, and, with it, a propane gas detector was designed. The sensor operated flawlessly at 250 °C at a concentration of 1000 ppm, with a response time of three seconds. The developed device is inexpensive and easy to implement.

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Section: Analysis Of the Dynamic Response Of The Znal 2 Osupporting

confidence: 89%

Section: Analysis Of the Dynamic Response Of The Znal 2 Omentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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Electrical Response of the Spinel ZnAl2O4 and Its Application in the Detection of Propane Gas

Guillén-Bonilla

Bonilla

Rodríguez-Betancourtt

et al. 2021

Applied Sciences

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“…Effective air pollution prevention and control measures are required when designing ventilation systems [36]. The results obtained from this study predict the nature of LPG dispersion from the chosen source (illegal car parked in an underground garage equipped with LPG installation), which plays a crucial role in the estimation of proper places for the sensors [37].…”

Section: Jet Ventilationmentioning

confidence: 88%

Numerical Description of Jet and Duct Ventilation in Underground Garage after LPG Dispersion

et al. 2021

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Contamination of toxic and odorous gases emitted from stacks in buildings located in an urban environment are potential health hazards to citizens. A simulation using the computational fluid dynamic technique may provide detailed data on the flammable region and spatial dispersion of released gases. Concentrations or emissions associated with garage sources and garage-to-house migration rates are needed to estimate potential exposures and risk levels. Therefore, the aim of the study was to use an original mathematical model to predict the most accurate locations for LPG sensors in an underground garage for vehicles powered with LPG. First, the three-dimensional geometry of an underground garage under a multi-family building was reconstructed. Next, two types of ventilation, jet and duct, were considered, and different sources of LPG leakage were assumed. Then, the Ansys Fluent software was applied as a solver, and the same initial value of released LPG (5 kg) was assumed. As a simplification, and to avoid the simulation of choked outflow, the emission from a large area was adopted. The results showed stagnation areas for duct ventilation in which gas remained for both the jet and duct ventilation. Moreover, it was observed that the analyzed gas would gather in the depressions of the ground in the underground garage, for example in drain grates, which may create a hazardous zone for the users of the facility. Additionally, it was observed that for jet ventilation, turbulence appearance sometimes generated differentiated gas in an undesirable direction. The simulation also showed that for blowing ventilation around the garage, and for higher LPG leakage, a higher cloud of gas that increased probability of ignition and LPG explosion was formed. Meanwhile, for jet ventilation, a very low concentration of LPG in the garage was noticed. After 35 s, LPG concentration was lower than the upper explosive limit. Therefore, during the LPG leakage in an underground garage, jet ventilation was more efficient in decreasing LPG gas to the non-explosive values.

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“…The electrical response of these semiconductors is based on the adsorption and desorption of oxygen ions on the surface [3,4] and the mobility of the charge carriers (holes or electrons) due to the temperature employed in the tests [1][2][3][4][5][6]. The variation in the electrical signal (resistance) shown by the semiconductor oxides depends on the detected gas and the type of semiconductor (p or n) [6,7]. In the gas sensor field, n-type semiconductors are the most studied [8] because they show excellent electrical response, thermal stability, and efficiency toward almost any gas (CO, O 2 , CO 2 , SO 2 , CH 4 , etc.)…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Sensing Response of Magnesium Antimoniate Oxide (MgSb2O6) in the Presence of Propane Atmospheres at Different Operating Voltages

Guillén-Bonilla,

Rodríguez-Betancourtt

et al. 2024

Sensors

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Nanoparticles of MgSb2O6 were synthesized using a microwave-assisted wet chemistry method, followed by calcination at 700 °C. Their ability to detect different concentrations of propane gas (C3H8) at various operating voltages was evaluated. The material’s crystalline phase was identified using X-ray powder diffraction (XRD). The morphology was analyzed by scanning electron microscopy (SEM), finding bar- and polyhedron-type geometries. Through transmission electron microscopy (TEM), we found particle sizes of 8.87–99.85 nm with an average of ~27.63 nm. Employing ultraviolet–visible (UV-Vis) spectroscopy, we found a band gap value of ~3.86 eV. Thick films made with MgSb2O6 powders were exposed to atmospheres containing 150, 300, 400, and 600 ppm of propane gas for dynamic testing. The time-dependent sensitivities were ~61.09, ~88.80, ~97.65, and ~112.81%. In addition, tests were carried out at different operating voltages (5–50 V), finding very short response and recovery times (~57.25 and ~18.45 s, respectively) at 50 V. The excellent dynamic response of the MgSb2O6 is attributed mainly to the synthesis method because it was possible to obtain nanometric-sized particles. Our results show that the trirutile-type oxide MgSb2O6 possesses the ability, efficiency, and thermal stability to be applied as a gas sensor for propane.

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A Gas Sensor for Application as a Propane Leak Detector

Cited by 8 publications

References 37 publications

Electrical Response of the Spinel ZnAl2O4 and Its Application in the Detection of Propane Gas

Electrical Response of the Spinel ZnAl2O4 and Its Application in the Detection of Propane Gas

Numerical Description of Jet and Duct Ventilation in Underground Garage after LPG Dispersion

Synthesis and Sensing Response of Magnesium Antimoniate Oxide (MgSb2O6) in the Presence of Propane Atmospheres at Different Operating Voltages

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