Concentrations Of Toxic Gases Research Articles

Assessing smoke toxicity of burning combustibles by four expressions for fractional effective dose

SummaryToxicity of smoke generated in a fire is difficult to measure accurately. That is because gas sensors for measuring rapidly varying concentrations of toxic gases are not yet developed. Simple expressions are searched for quick measurement in assessing smoke toxicity practically. Four equations on calculating fractional effective dose (FED) related to toxic effluents were reported in the literature, each based on different assumptions. FED value was proposed to be calculated based on peak carbon monoxide concentration and peak carbon dioxide concentration, and transient carbon monoxide, carbon dioxide, and oxygen concentrations. The four values were compared in this article using literature data on toxic gases from different materials measured by (i) cone calorimeter; (ii) full‐scale burning tests; and (iii) tunnel full‐scale tests. Measured carbon monoxide, carbon dioxide, and oxygen concentrations by standard equipment of oxygen consumption calorimeters were used to calculate the four FED values. It is found that the values of FED based on peak carbon monoxide and carbon dioxide concentrations (denoted as FED2) are similar to the average values of FED calculated from the updated equation in the literature using the oxygen consumption calorimeters. Putting the values of FED2 in fire safety design guides is then recommended.

Synthesis, characterization, and gas sensing properties of Fe3O4/FeOOH nanocomposites for a mass-type gas sensor

Fe3O4/FeOOH nanocomposites were synthesized by a simplistic precipitation method for high-performance gas sensing applications. A spray-coating method was used to deposit a sensitive film of Fe3O4/FeOOH nanocomposites on a quartz crystal microbalance (QCM). The structural and morphological characteristics were analyzed by using X-ray diffraction (XRD), scanning electron microscope (SEM), energy dispersive X-ray spectrometry (EDS), Fourier transforms infrared (FTIR) spectroscopy, and a vibrating sample magnetometer (VSM). The average diameter and length of the FeOOH nanorods were 30 and 100 nm, respectively. The maximum saturation magnetization of the prepared Fe3O4/FeOOH nanocomposites obtained a value ~30 emu g−1. The QCM sensor based on the Fe3O4/FeOOH nanocomposites was measured with various concentrations of toxic gases (CO, NO2, SO2) at room temperature. The gas sensing results indicated that the developed sensor had a considerable potentiality to apply for toxic gas sensors with a high detection sensitivity, repeatability, and good stability.

Detection of Hazardous Gas Mixture in the Smart Kitchen Using an Electronic Nose Under Interference Gas Environment

Introduction For a long time, due to various factors such as kitchen gas, house decoration and living habits, concentrations of toxic and harmful gases in the kitchen are likely to be much higher than national standards in a short period of time. High concentrations of toxic and harmful gases can cause extremely adverse effects on the human body, which can lead to physical discomfort and even serious accidents such as fires and explosions.In the past few years, some researches focused on the development of a more specific and intelligent gas detection system, including the detection of harmful gases in industrial environments [1], dairy industry [2] and living environment [3]. However, there are few studies on graded, low-cost, wide-range, cheap, multifunctional and simultaneous gas detection systems for mixed harmful gases in kitchen so far. E-nose System The potential toxic and harmful gases in the kitchen are mainly carbon monoxide and methane. However, formaldehyde is also present in the kitchen and acted as interference gas in this study. Therefore, a corresponding detection system was developed to evaluate the concentrations of the mixed harmful gases using a MOS gas sensor array including MP-9, MP-4, MP503, TGS821, TGS816, TGS2602. Nearly half of collected samples contained formaldehyde. Besides, a SHT20 sensor is used to monitor humidity and temperature. This system (Fig.(A)) consists of three parts: the gas blender module, the detection module and the concentration identification module.The gas blender mixes different gases and provides required mixture for detection. All mixed gas samples are diluted by the standard air in order to make the MOS sensors work properly. The standard air is directly discharged into the gas chamber for cleaning. After that, the detection module collects the response of the sensor array to the mixed gas under the control of a microcontroller unit. Here, we adopted a differential amplification and low-pass filter circuit to process the initial sensor voltage signal. Simultaneously, the signals are sent to the software on the computer for further analyzing. Method According to China‘s national indoor air quality standard, combustible gas detection standard and the detection range of MOS sensors, the concentration levels of target gases were set as Fig.(B).In this study, the actual concentrations of different gases in the mixed gas were calculated by the gas blender. The flow rate was set to 1000 mL/min constantly. The experiment process consists of several parts. First, the sensor array was preheated for more than 30 minutes in advance and cleaned in standard air for nearly 30 minutes until the voltage of each sensor was below the corresponding threshold. Next, gas blender injected the mixed gas sample into the gas chamber at a constant flow rate for 5 minutes. In the meantime, the feature parameters of each sensor’s response were extracted and calculated by the MCU in real time. Finally, the sensor array was cleaned for 5 minutes. The extracted features including baseline, maximum positive slope, maximum, peak area, temperature and humidity were all considered in the LDA model. A total of 316 samples were collected. 183 of them contain formaldehyde ranging randomly from 1-40 ppm. In addition, 90% samples for training, 10% for testing. Results and Conclusions During model training, the LDA model can effectively distinguish different levels with or without formaldehyde for both target gases (Fig.(C), (D)). The testing accuracies of LDA model for carbon monoxide and methane without formaldehyde samples are 91.89% and 97.30%, respectively. When there is formaldehyde interference, the accuracies are 80.95% and 92.06%, respectively. Therefore, the interference of formaldehyde has a greater impact on the identification of carbon monoxide. Besides, it is worth noting that carbon monoxide is difficult to distinguish at lower concentration levels, while methane is difficult to distinguish at higher levels. This may be due to the actual detection concentration is close to the upper or lower detection limits of the sensor, causing the sensor to be insensitive at lower levels and too saturated at higher levels. But this study still proves that the system can well meet the requirements of the detection of harmful gases in the interference environment. Figure 1

High Performance UV-LED Activated Sensor Development By Modulating the Morphology and Composition

Metal Oxide Semiconductor (MOS) gas sensors have been studied for monitoring indoor/outdoor air pollutants. A drawback of conventional chemical-resistive gas sensing is the high operating temperature (up to 500°C) that is required for surface reactions. The high temperature operation, however, causes drift problems and makes sensors unsafe for environments containing flammable gases.Ultraviolet light-emitting diode (UV-LED) is a new technological field that has recently seen rapid improvements and novel possible applications. These include the development of UV-LED based gas sensors. UV photons emitted from UV-LED could activate sensors to allow detection of chemicals at ambient temperature. UV irradiation can also improve the sensor performance in harsh environments, where SO2 or NOx gases are present, through desorbing surface contaminants. The state-of-the-art ultraviolet light emitting diode (UV-LED) that emit radiation at a power of a few milli-watts is a promising UV source for this application.UV-activated sensors have a variety of advantages, compared to the traditional chemi-resistive metal oxide semiconductor (MOS) sensors, such as higher stability, lower preparation time, and the ability to safely detect flammable gases. The advances in ultra-violet light emitting diode (UV-LED) technology and its utilization in the gas sensing industry may offer a breakthrough in UV-based sensors, providing several important progresses such as broader application, smaller size, and higher efficiency of the developed sensors.Among the various metal oxides that have been studied for gas sensing applications, ZnO nano-materials have shown promisebecause of high electron conductivity features. ZnO has strong luminescent properties, broad UV absorption, and high stability. Thephoto-activity of ZnO can be improved by synthesizing one-dimensional (1D) nanostructuresand by functionalizing with catalytic metal nanoparticles. This combination lowers the requiredactivationenergy and reduces the recombination rate of photo-generated charge carriers.We will present the fabrication of a sensitive 1D nanostructure ZnO gas sensor decorated with Pt nanoparticles to detect low concentrations of toxic gases at room temperature under UV-LED irradiation (Figure 1). ZnO nanoparticles and nanowires decorated with platinum nanoparticles in different loading concentrations were prepared to detect low concentrations of NO2 under UV-LED irradiation. Solution precipitation, self-assembly crystallization, and photo-deposition techniques were used to synthesize the sensing material. The synthesized sensors at different stages of development were characterized by X-ray diffraction (XRD) and field emission scanning electron microscopy (FE-SEM) analyses.To obtain a certain visual evidence of Pt nanoparticleson the surface of ZnO nanowires, High-resolution transmission electron microscopy (HRTEM) and STEM imaging were employed. The presence of Pt nanoparticles was further confirmed through high-angle annular dark-field (HAADF) STEM analysis.Although the sensing response of the pristine ZnO nanoparticles was relatively high (0.4) for NO2 detection, the sensing response improved significantly using ZnO nanowires in the identical photo-activation settings. The decoration ofthe surface of the ZnO nanowires with Pt nanoparticles further enhanced the sensing performance, whereas the 0.1wt% Pt-decorated ZnO nanowire sensor exhibited a response of more than one order of magnitude higher (1.5) than the response generated by the ZnO nanoparticles. This improved performance is attributed to the role of Pt active sites in promoting NO2 adsorption on the ZnO nanowires’ surface as well as enhancing the layer electron utilization.We will present the results and discuss how UV-LED has the potential to significantly impact sensor development and portable gas monitoring systems by enabling novel sensor design concepts. Figure 1

Toxic gas and respirable dust concentrations and emissions from broiler and cage-layer barns in the Canadian Prairies.

This study monitored concentrations and emissions of ammonia (NH3), hydrogen sulfide (H2S), and respirable dust for a commercial broiler and a cage-layer barn in the Canadian Prairies over a year between March 2015 and February 2016. Seasonal concentration and emission profiles were acquired by monthly measurements, while diurnal profiles were generated in different seasons. The indoor air quality was evaluated considering both the individual and the additive health effect (respiratory irritation) of the three air pollutants. In winter, both 8-h and 15-min exposure limits (threshold concentrations) of NH3 were exceeded in the broiler barn; the highest additive level was more than two times of the limit. Seasonal average emissions of NH3, H2S, and respirable dust were 57gd-1AU-1, 1.35gd-1AU-1, and 1.99gd-1AU-1, respectively, for the layer barn, all with higher levels in the mild and warm seasons than in the cold season. The emission data were only obtained for the worst-case scenarios (last week of the production cycle) of the broiler barn, with annual averages of 92gd-1AU-1 for NH3, 1.19gd-1AU-1 for H2S, and 4.32gd-1AU-1 for respirable dust, with obvious higher NH3 levels in winter. Additionally, manure removal once every 3-4days for the layer barn reduced NH3 emissions by 62% and 90% in the cold and mild seasons, respectively. This study also found significant negative influence of outdoor T (Tout) on NH3 emissions for the broiler barn but positive impact of Tout on NH3 emissions for the layer barn.

Design and Attainment Assessment of Different Protocols for Smart Industry to Observe and Control Gas Leakage Employing WSN

Harmful gases leaking from the equipment that are installed in the industries cause huge loss of lives of the workers as well as people living nearby the industries. The main causes for the gas leakage are poorly maintained machines, leaky storage tanks. So, focusing on the concentration of harmful toxic gases, a virtual analysis has done using QualNet 6.1. Different numbers of nodes have dropped randomly in different terrain areas. Three protocols LRWPAN, LRWPAND, LRWPANDMC have been used to virtually analyze the gas leakage scenario. These sensors detect the gases when the leakage is near about or more than the limit. At each time some nodes will be in sleep mode and others will be in active mode, this mechanism will increase the lifetime of the battery, as changing battery frequently will not be possible especially in remote areas. The crucial profit of this paper is to show the network performance which is simulated with a sink node receiving packets for different time duration and at different frequencies. The idea is to find out the optimal and efficient network for fast information flow with 50, 100, 300 nodes. The terrain area of the network is 100×50 m2, 100×100 m2, 500×500 m2 with the communication range of 10 m. The routing protocols implemented are Low-Rate Personal Area Network (LRPAN), Low-Rate Personal Area Network with Drift (LRPAND) and Low-Rate Personal Area Network with Drift and Multi-Channel. This paper has evaluated and analyzed the influence of packet flow at the different frequencies of 2.425, 2.450, 2.475 and 2.480 GHz. It is analyzed that performance of each protocol has varied significantly for different number of nodes. The performance of the network is improved by the different frequencies instead of 2.4 GHZ frequency. The parameters average end to end delay (seconds), jitter (seconds), throughput (bits per second) and network lifetime (hours) for different protocols such as LRPAN, LRPAND and LRPANDMC for different numbers of nodes 50, 100 and 300 are evaluated and compared. The optimum results are obtained by the LRPANDMC in the simulation process. Evaluation and analysis of the influence of different protocols on different number of nodes for different parameters has been done to determine most effective protocol. This type of network can be used in oil and gas industries, petroleum industries at remote areas where there are high chances of gas leakage incidents. The aim is to provide information in real-time scenario virtually.

Case Studies on The Use of LiveLink for MATLAB for Evaluation and Optimization of The Heat Sources in Experimental Borehole

In the Czech part of the Upper Silesian Coal Basin (Moravian-Silesian region, Czech Republic), there are many deposits of endogenous combustion (e.g., localized burning soil bodies, landfills containing industrial waste, or slag rocks caused by mining processes). The Hedwig mining dump represents such an example of these sites where, besides the temperature and the concentrations of toxic gases, electric and non-electric quantities are also monitored within the frame of experimentally proposed and patented technology for heat collection (the so-called “Pershing” system). Based on these quantities, this paper deals with the determination and evaluation of negative heat sources and the optimization of the positive heat source dependent on measured temperatures within evaluation points or on a thermal profile. The optimization problem is defined based on a balance of the heat sources in the steady state while searching for a local minimum of the objective function for the heat source. From an implementation point of view, it is the interconnection of the numerical model of the heat collector in COMSOL with a user optimization algorithm in MATLAB using the LiveLink for MATLAB. The results are elaborated in five case studies based on the susceptibility testing of the numerical model by input data from the evaluation points. The tests were focused on the model behavior in terms of preprocessing for measurement data from each chamber of the heat collector and for the estimated value of temperature differences at 90% and 110% of the nominal value. It turned out that the numerical model is more sensitive to the estimates in comparison with the measured data of the chambers, and this finding does not depend on the type optimization algorithm. The validation of the model by the use of the mean-square error led to the finding of optimal value, also valid with respect to the other evaluation.

Risk Assessment of Gas Leakage from School Laboratories Based on the Bayesian Network.

In recent years, concerns about the safety of laboratories have been caused by several serious accidents in school laboratories. Gas leaks in the laboratory are often difficult to detect and cause serious consequences. In this study, a comprehensive model based on the Bayesian network is established for the assessment of the gas leaks evolution process and consequences in school laboratories. The model can quantitatively evaluate the factors affecting the probability and consequences of gas leakage. The results show that a model is an effective tool for assessing the risk of gas leakage. Among the various factors, the unsafe behavior of personnel has the greatest impact on the probability of gas leakage, and the concentration of toxic and harmful gases is the main factor affecting the consequences of accidents. Since the probability distribution of each node is obtained based on the experience of experts, there is a deviation in the quantitative calculation of the probability of gas leakage and consequences, but does not affect the risk analysis. This study could quantitatively assess the probability and consequences of gas leakage in the laboratory, and identify vulnerabilities, which helps improve the safety management level of gas in the school laboratory and reducing the possibility of gas leakage posing a threat to personal safety.

РАЗРАБОТКА МЕТОДОВ И ТЕХНИЧЕСКИХ СРЕДСТВ НЕЙТРАЛИЗАЦИИ СЕРОСОДЕРЖАЩИХ СОЕДИНЕНИЙ В АТМОСФЕРЕ КАЛИЙНЫХ РУДНИКОВ

The study is devoted to the normalization of the mine atmosphere in potash mines. We propose the technique of neutralizing toxic gases (hydrogen sulfide and methyl mercaptan) in a mine atmosphere, which is based on photochemical method. It allows reducing concentrations of toxic gases to the maximum permissible values. The developed technique of neutralizing sulfur-containing gases can be used in potash mines.

OPTIMIZATION OF THE EVACUATION ROUTE IN CHEMICAL PLANTS BASED ON THE DEPTH-FIRST SEARCH ALGORITHM

Optimal evacuation routes are crucial to protect workers safety when accidental leakage of toxic gas occurs in chemical plants. However, the majority of route optimization focuses on the transport field and few on the evacuation routing optimization in chemical plants. This paper proposes a dynamic evacuation routing optimization method for chemical plants under toxic gas release scenarios. From the complete accident scenario set (CASS) built with wind fields and leakage sources, the leakage probability can be quantitatively represented. Based on the computational fluid dynamics (CFD) simulation, the consequences of toxic gas dispersion including the time-dependent concentration under different leakage scenarios can be obtained. Subsequently, considering the time-dependent toxic gas concentration and exposure time, the dynamic cumulative individual risk (CIR) can be calculated by applying the dynamic dose-response model (DDR). Then according to the simplified evacuation topology, the Depth First Search (DFS) algorithm is employed to define all evacuation routes connected with arcs. With the objective of minimizing CIR, an evacuation route optimization model is proposed and solved by MATLAB. Results demonstrate that the proposed method can hopefully minimize the CIR in chemical plants when they are facing toxic gas release and poisoning risks.

Impact of Apartment Tightness on the Concentrations of Toxic Gases Emitted During a Fire

Due to the thermal modernization process of old residential buildings, there has been a significant increase in the air-tightness of apartments, which may contribute to the deterioration of the safety of users and rescue teams in a fire, for example, the emergence of a very dangerous backdraft phenomenon. The aim of the study was to investigate the impact of air-tightness of premises on selected fire parameters in particular toxic gas concentrations, which is the most common cause of deaths of people due to fires. In the research, an experimental method was used, consisting of the measurement of concentrations of gases such as oxygen, carbon monoxide and dioxide, hydrogen sulfide, propylene, acetylene, hydrogen and nitric oxide, and dioxide, which most often give off during a fire due to modern interior design materials. Two fire tests were carried out, one in a sealed apartment and the other unsealed (one window wing half-open). The concentrations of the previously mentioned gases obtained in both tests are presented and then compared with each other. Based on the analysis, conclusions have been formulated, which suggest that increasing the tightness may increase the toxicity of the fire environment.

Internet of things based industrial environment monitoring and control: A design approach

In this research an internet of things (IoT) system is designed for the purpose of industrial environment monitoring and control. The system is mainly composed of control and sensor units. Control unit has the responsibility of managing the received data form the sensor unit and then executing the developed control algorithm based on the measured parameters. NodeMCU development kit is used as the core of the control unit. The senor unit contains gas and temperature sensors utilized for measuring the temperature and concentration of toxic gases in the monitored space. A buzzer has also been embedded in the sensor unit for alerting the occupants acoustically in the danger situations. If the monitored temperature gets higher or lower than the set levels, the air conditioning system will be automatically operated. Similarly, the fan (ventilation) system will be operated if the level of toxic gases becomes high. A mobile application, based on Blynk platform, is then developed to enable the wireless monitoring and control of the environment by the in charge people. In addition to the automatic and wireless control the manual control capability is considered in the developed IoT system.

Smart Manhole Toxic Gas Identification and Alerting System

Even nowadays, sewage systems are cleaned by the manual power. Somewhere they recently stated that “More Indians were dying in cleaning sewers than fighting terrorists in Kashmir”. Sewer gas is a composite amalgamation of venomous and non-hazardous gases, which is collected in sewage systems. Predominantly it also comprises that oxide of carbon, sulphur, nitrogen, ammonia and methane due to the decomposition of organic household or industrial wastes. During the maintenance practice, Sewer gases cause the health issues and fatal death to the labors also due to untreated disposal of petroleum products such as gasoline and mineral spirits. To conquer these impacts, in this proposed system, by using a set of integrated sensors MQ-4, MQ-7, MQ137 were incorporated with microcontroller unit process and LCD Display to quantify toxic gases which is produced in the system. It could be recognize the scale of toxicants and then intimated to the workers to acquire the safety precautions before entering into the manholes. The sensing range for the leak detection sensor should be from 300 ppm to 10,000 ppm. In order to reduce the toxic gases concentration, Sprinkler mechanism is provided with the resource chemical for detoxification treatment. Whenever the gas concentration level exceeds the specified threshold level, an actuator mechanism triggers the sprinkler. To upkeep the sewerage system and Prohibiting Manual Scavengers and their Rehabilitation Act, 2013, labors continually taking risk in their health and life. But they were paid for merely low wages. Despite proactive orders of the Supreme Court, the implementation of the directives remains unrealized, in the wake of frequent deaths. In this special episode of Banega Swachh India campaign, we take a look at how these deaths leave the workers’ family devastated and yet no one claims responsibility for the deaths.

Anesthetic toxic isoflurane and health risk assessment in the operation room in Abadan, Iran during 2018

IntroductionAnesthetic gases are very important for health among health care worker (HCWs) and patients in medical centers. Operating rooms (ORs) is the most important ward that use anesthetic gases. Isoflurane gases is very dangerous for HCWs. ObjectiveIn this study, we have associated the concentration of anesthetic toxic isoflurane gases (ppm) and the health risk assessment due to exposure to common anesthetic gases in Valiasr and Shahid Beheshti teaching hospital operating room during 2018. MethodsIn this study, we used the active sampling system by portable pump SKC and tubes (sorbent Tube Tenax TA 250 mg) for detection of isoflurane concentration (ppm). Different points of the operating rooms were selected for sampling. Hazard index (HI) quantified by calculating the non-cancer causing anesthetic toxic isoflurane gases. ResultsAccording result this study, the Valiasr and Shahid Beheshti had the lowest and the highest level of isoflurane. Based on result this study, level of isoflurane on indoor air quality in the operation room in Valiasr and Shahid Beheshti hospital were 2.129 and 2.436 ppm, respectively. According to the results from the current study, hazard index was under 1.0 and it amount showed that no significant risk of adverse health endpoint attributed to exposure to level of isoflurane in Valiasr and Shahid Beheshti teaching hospital operating room during 2018. ConclusionAccording Result this study the average concentration of isoflurane and the health risk assessment in Valiasr and Shahid Beheshti teaching hospital operating room during 2018 because of flaw in the ventilation system was significantly higher than standard.

ANALYSIS OF ECOLOGICAL PROPERTIES OF TRADITIONAL AND ALTERNATIVE AVIATION GAS COMPONENTS

The work is devoted to the analysis of environmental properties of aviation gasolines and substantiation of its optimal component composition for providing sufficient exploitation and environmental performance. During the study the technogenic impact of processes of oil extraction and processing was considered. The processes of oil refining and aviation gasolines production were analyzed. Environmental properties of conventional and alternative aviation gasolines were analyzed in the presented article. The influence of individual hydrocarbon components, found in gasolines, on its environmental properties as well as level of toxicity of hydrocarbon components was shown. It was found that decreasing of aromatic hydrocarbons content in gasolines with simultaneous application of oxygenate, can improve the composition of aviation gasolines. It can help to reduce formation of carbon monoxide and unburned hydrocarbons emissions during combustion. Increasing of octane number causes reduction of toxic gases concentration in emissions; thus environmental properties of aviation gasolines are improved. Later the comparative characteristics of physical-chemical properties of conventional aviation and motor gasolines, some oxygenates, such as methanol, ethanol and buthanol, and hydrogen was developed and analyzed. It was found that adding oxygenates, mainly ethanol, into the composition of alternative aviation gasoline helps improving its octane number, thus it will have positive effect on exploitation of aviation internal combustion engines, as well as improving exhaust gases composition in a result of gasolines combustion. It was proposed the optimal content of ethanol oxygenate in the composition of aviation gasoline – 25 %. In a result of the work it was concluded that using of oxygenates improves environmental properties of alternative aviation gasolines. This may contribute to improving of exploitation properties of aviation gasolines and also minimization of aviation industry impact on environment.

A comprehensive investigation on the thermal and toxic hazards of large format lithium-ion batteries with LiFePO4 cathode

Toxic gases released from lithium-ion battery (LIB) fires pose a very large threat to human health, yet they are poorly studied, and the knowledge of LIB fire toxicity is limited. In this paper, the thermal and toxic hazards resulting from the thermally-induced failure of a 68 Ah pouch LIB are systematically investigated by means of the Fourier transform infrared spectroscopy (FTIR) and 1/2 ISO full scale test room. The LIBs with higher state of charge (SOC) are found to have greater fire risks in terms of their burning behavior, normalized heat release rate, and fire radiation, as well as the concentration of toxic gases. Specifically, the thermal hazards are evaluated by combining the effects of convective and radiative heat. The major toxic gases detected from the online analysis are CO, HF, SO2, NO2, NO and HCl. Furthermore, Fractional Effective Dose (FED) and Fractional Effective Concentration (FEC) models are used to quantitatively assess the overall gas toxicity. Results show that the effects of irritant gases are much more significant than those of asphyxiant gases. HF and SO2 have much greater toxicity than the other fire gases. The maximum FEC value is approaching the critical threshold in such fire scenarios.

Removal of Smoke and Toxic Gases Through Sprinkler Head Spray

This study was conducted with the aim of reducing the concentration of smoke and toxic gases by quickly capturing large amounts of these substances using a venturi tube and sprinkler head in a fire. To this end, a new experimental model sprinkler head has been developed. The ability to remove carbon monoxide and smoke was tested using a standard sprinkler head with a scaled-down chamber and smoke of cigarettes. The carbon monoxide concentration and visibility were measured at 1, 2, and 3 min after filling the chamber with smoke. The proto-model confirmed a significant drop in the carbon monoxide concentration and a remarkable smoke dilution at a discharge pressure of 0.1 MPa. Therefore, the test model could extend the evacuation time and stay time by removing smoke and toxic gases. Keywords: Smoke and Toxic Gas, Venturi Effect, Sprinkler Head, Concentration Drop, Visibility

Evaluation of Post-blast Re-entry Times Based on Gas Monitoring of Return Air

Blasting is the main method of production in many non-coal underground mining operations and produces multiple toxic gases as a result. The Mine Safety and Health Administration (MSHA) requires mine operators to measure the level of toxic gases in mines as frequently as necessary to ensure they are below regulatory safety limits. The current practice uses portable gas monitors to check the concentrations of toxic gases after a fixed post-blast time. This paper studies the application of a gas monitoring system in the return entry of a limestone mine to determine a safe re-entry time. The National Institute for Occupational Safety and Health (NIOSH) conducted such a monitoring program in a limestone mine from September 2016 through May 2018. NIOSH/PMRD (Pittsburgh Mining Research Division) is endeavoring to develop workplace solutions to improve detection of and reduce the risk of hazardous conditions. This study showed that the use of gas monitoring in the return air can be a useful tool at the mine operator’s disposal to detect and reduce the risk of hazardous conditions and also to reliably estimate the re-entry time.

Additions of Tropospheric Ozone (O3) in Regional Climates (A case study: Saudi Arabia)

Anthropogenic activities are responsible for enhancing the concentration of various toxic gases that produces bad Ozone in the troposphere which is harmful to human health. The specific objective of this research was to analyze the spatio-temporal variations in a vertical column of Ozone (O3) over Saudi Arabia during 2006-2016 using Atmospheric Infrared Sounder (AIRS) onboard AQUA platform and AErosol RObotic NETwork (AERONET) data. The results show that the optical depth of Ozone column varied from 252 Dobson Units (DU) to 264 DU. The main reason of this variation corresponds to the increase in O3 precursors including Carbon Dioxide (CO2), Nitrogen Dioxide (NO2) and Sulfur Dioxide (SO2). The concentration of CO2 varied between (379-401) Parts Per Million (PPM), SO2 varied (3.5x10-6 - 4x10-6kg m-2) kg m-2 and NO2 varies (2.25x1015 - 2.5x1015)1/cm2 during the investigated timeframe. The results confirm that NO2 and SO2 have contributed directly in O3 formation while CO2 just increased regional temperatures that enhanced the optical depth of O3. Keywords: AIRS, AERONET, Carbon dioxide, Nitrogen dioxide, Sulfur dioxide, Aerosol optical depth and Dopson Unit.

Additions of Tropospheric Ozone (O3) in Regional Climates (A case study: Saudi Arabia)

Anthropogenic activities are responsible for enhancing the concentration of various toxic gases that produces bad Ozone in the troposphere which is harmful to human health. The specific objective of this research was to analyze the spatiotemporal variations in a vertical column of Ozone (O3) over Saudi Arabia during 2006-2016 using Atmospheric Infrared Sounder (AIRS) onboard AQUA platform and AErosol RObotic NETwork (AERONET) data. The results show that the optical depth of Ozone column varied from 252 Dobson Units (DU) to 264 DU. The main reason of this variation corresponds to the increase in O3 precursors including Carbon Dioxide (CO2), Nitrogen Dioxide (NO2) and Sulfur Dioxide (SO2). The concentration of CO2 varied between (379-401) Parts Per Million (PPM), SO2 varied (3.5x10-6 - 4x10-6kg m-2) kg m-2 and NO2 varies (2.25x1015 - 2.5x1015)1/cm2 during the investigated timeframe. The results confirm that NO2 and SO2 have contributed directly in O3 formation while CO2 just increased regional temperatures that enhanced the optical depth of O3.