Modeling of Ammonia Emission in the Petrochemical Industry

Abbaslou, Hossein; Karimi, Ali

doi:10.5812/jjhs.94101

Cited by 10 publications

(5 citation statements)

References 18 publications

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“…1(c) presents the results of the blast area of a VCE. The red zone in the figure indicates an 8.0 psi (55.15 kPa) overpressure which was never exceeded; the orange zone was as large as 141 m where the overpressure was 3.5 psi (24.13 kPa) (Abbaslou and Karimi, 2019). The yellow zone was as large as 210 m where the overpressure was 1.0 psi (6.89 kPa).…”

Section: Death and Minor Injury Radius For Vce Of Butyl Acrylatementioning

confidence: 98%

Emission rates, ALOHA simulation and Box-Behnken design of accidental releases in butyl acrylate tank - case study

Saloglu

Dertli

Mohammadi

et al. 2022

Production Engineering Archives

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The leakage of hazardous compounds in chemical industries has always been one of the factors threatening workers, plants, and the environment. Among them, butyl acrylate is one of the most harmful materials that are widely used in chemical plants. In the present study, a butyl acrylate tank located in a real tank farm in Kocaeli-Turkey was analyzed for the examination of emissions and trinitrotoluene (TNT) equivalent explosion model of the vapor cloud. Areal Locations of Hazardous Atmospheres (ALOHA) program was used to define threat zones of butyl acrylate leakage based on different scenarios, such as a leakage from the tank without fire, burning as a jet fire, and also burning as a fireball during Boiling Liquid Expanding Vapor Explosion (BLEVE). In addition, since the most important parameters that enhance the effects of explosion and the spread of volatile organic compounds (VOCs) are wind speed, filling ratio of the tanks, and temperature, the interaction of these parameters on the threat zones and the highest threat zones of explosions were investigated using the Box-Behnken experimental design and one-way Analysis of Variance (ANOVA), respectively. As butyl acrylate, one of the most dangerous chemicals for industrial facilities, and its explosion effects have not been studied so far, it can be safely mentioned that this paper representing the first study in the literature is highly original and novel.

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Section: Death and Minor Injury Radius For Vce Of Butyl Acrylatementioning

confidence: 98%

Emission rates, ALOHA simulation and Box-Behnken design of accidental releases in butyl acrylate tank - case study

Saloglu

Dertli

Mohammadi

et al. 2022

Production Engineering Archives

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“…Figure 6 presents a computational algorithm and procedure of risk assessment. According to typical studies on the modeling of ammonia leakage and release [64][65][66][67][68][69][70][71][72][73][74][75][76][77], the common algorithmic diagram for the computational analysis of ammonia leakage is shown in Figure 5, and the computational algorithm and procedure are presented in Figure 6. The six steps required to use computational fluid dynamics (CFD) for the modeling and consequence analysis of ammonia leakage or accidents include the following:…”

Section: Cfd and Theorical Analysismentioning

confidence: 99%

“…The algorithm in Figure 7 below describes a procedure for risk analysis using riskbased methods similar to those seen in [78][79][80][81][82][83]. According to typical studies on the modeling of ammonia leakage and release [64][65][66][67][68][69][70][71][72][73][74][75][76][77], the common algorithmic diagram for the computational analysis of ammonia leakage is shown in Figure 5, and the computational algorithm and procedure are presented in Figure 6. The six steps required to use computational fluid dynamics (CFD) for the modeling and consequence analysis of ammonia leakage or accidents include the following: (i) Identify the simulation case: This step is to clarify the purpose of the simulation and which leakage/release case will be addressed.…”

Section: Cfd and Theorical Analysismentioning

confidence: 99%

Safety Assessment of the Ammonia Bunkering Process in the Maritime Sector: A Review

Duong

Ryu

Song³

et al. 2023

Energies

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One of the main goals of the shipping industry is to decarbonize the fuels used in maritime transportation. Ammonia is thought to be a potential alternative for hydrogen storage in the future, allowing for CO2-free energy systems. Ammonia’s beneficial characteristics with regard to hydrogen storage include its high volumetric hydrogen density, low storage pressure, and long-term stability. However, ammonia is characterized by toxicity, flammability, and corrosiveness, making safety a challenge compared to other alternative fuels. In specific circumstances, leakage from ammonia bunkering can cause risks, dispersion, and unsafe areas due to its flammability and toxicity. Based on an analysis of 118 research papers and 50 regulations and guidelines, this review report evaluates various aspects of the hazards associated with the ammonia bunkering processes, considering both current and future implications. This report also includes the latest advancements and potential developments related to the safety of ammonia as a marine fuel. Several related regulations and standards for ammonia supply systems are discussed. This paper examines experiments and numerical investigations conducted using different methods of ammonia bunkering, such as terminal-to-ship, ship-to-ship, and truck-to-ship transfers. This review shows that the toxicity of ammonia is more relevant to the topics of vapor cloud dispersion and ammonia bunkering than its flammability. Finally, the main challenges and recommendations for the implementation of ammonia bunkering and further development of ammonia as a marine fuel are proposed. This review suggests new directions to overcome the disadvantages and research gaps associated with the leakage of ammonia during bunkering periods.

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“…In addition, its depending on the season and location, wind patterns might change significantly. Sea breezes frequently influence wind direction in coastal regions like Bintulu, while storms and pressure systems can have an impact on wind speed (Alizadeh et al, 2014;Abbaslou, 2019). The movement and effects of ammonia in a particular area can be predicted using a wind rise and the Aloha software (see table 2 and table 3), the computational model for forecasting chemical emissions.…”

Section: Utilizing Wind Rose For Modelling Of Ammonia Release With Al...mentioning

confidence: 99%

Utilizing Wind Rose Information for the Prediction of Ammonia Migration

Gafor,

Adam Assim,

Marzuki

et al. 2023

IJARBSS

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Exposure to high concentrations of ammonia can be harmful to human health. Ammonia is a strong irritant and can cause respiratory problems, such as coughing, wheezing, and shortness of breath. Prolonged exposure to high concentrations of ammonia can also cause damage to the lungs, and in severe cases, can lead to death. In addition to respiratory effects, ammonia exposure can also cause eye, nose and throat irritation, skin rashes and other symptoms. At high concentrations, ammonia can also cause chemical burns to the skin and eyes. The severity of the health effects will depend on the concentration of ammonia, the duration of exposure, and the specific characteristics of the individual exposed, such as their age, health, and any pre-existing respiratory condition. Wind can affect the migration of ammonia by influencing the dispersion and diffusion of the gas. Strong winds can disperse ammonia over a wide area, reducing the concentration in any one location. Conversely, calm winds can cause ammonia to accumulate in a specific area, leading to higher concentrations. The direction and strength of the wind can also affect the direction of ammonia migration, potentially carrying the gas towards or away from sensitive areas such as residential neighbourhoods or wildlife habitats. A wind rose is a graphical representation of the distribution of wind speeds and directions at a specific location. It is often used to understand the dominant wind patterns and how they may influence the dispersion of pollutants such as ammonia. The direction from which the wind is blowing is represented on the outer circle, with the wind speed represented on the inner circles. When it comes to ammonia dispersion, the wind rose can be used to understand how the dominant wind patterns in a specific location may influence the spread

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Modeling of Ammonia Emission in the Petrochemical Industry

Cited by 10 publications

References 18 publications

Emission rates, ALOHA simulation and Box-Behnken design of accidental releases in butyl acrylate tank - case study

Emission rates, ALOHA simulation and Box-Behnken design of accidental releases in butyl acrylate tank - case study

Safety Assessment of the Ammonia Bunkering Process in the Maritime Sector: A Review

Utilizing Wind Rose Information for the Prediction of Ammonia Migration

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