Global ETD Search

131	Avaliação da presença de vapores no solo em antiga área industrial contaminada por hidrocarbonetos : concentrações medidas e simuladas / Soriano Junior, Roberto. January 2009 (has links) Orientador: José Eduardo Zaine / Banca: Scandar Gasperazzo Ignatius / Banca: Fábio Augusto Gomes Vieira Reis / Resumo: A contaminação de solos e água subterrânea por hidrocarbonetos derivados de petróleo tende a liberar vapores que migram da subsuperfície para o ar, expondo, principalmente o ser humano à inalação de compostos que podem oferecer risco a sua saúde. Porém a volatilização destes compostos pode indicar as possíveis fontes de contaminação em subsuperfície. As agências de proteção ambiental, como a EPA (Environmental Protection Agency), nos Estados Unidos, e os órgãos ambientais no Brasil, como a CETESB - Companhia de Tecnologia de Saneamento Ambiental, tem recomendado a avaliação dos Compostos Orgânicos Voláteis - VOC, por meio da técnica denominada Soil Gas Survey. Esta técnica vem sendo largamente utilizada por empresas de consultoria ambiental. Consiste na verificação de concentrações anômalas de VOC no solo in-situ, por meio de analisadores portáteis como FID, PID e Oxidação Catalítica, balizando os trabalhos de investigação e direcionando a quantidade de sondagens e poços de monitoramento para coletas de amostras de solo e água subterrânea para análises químicas. Desta forma o presente trabalho avaliou a presença de possíveis vapores em uma antiga área industrial abandonada contaminada por BTEX e Organoclorados. Esta avaliação foi feita por meio da técnica Soil Gas Survey com a utilização do analisador portátil de Oxidação Catalítica e simulou a volatilização dos contaminantes presentes na água subterrânea por meio do modelo matemático RBCA - Risk- Based Corrective Action Tool Kit Version 2. Os baixos resultados da modelagem da volatilização dos compostos confirmaram os resultados nulos na campanha de avaliação dos VOC no solo pela técnica Soil Gas Survey. Estes resultados sugerem à não capacidade destes compostos chegarem até a superfície. / Abstract: The contamination of soils and underground water by hydrocarbonates of petroleum derivatives tend to release vapors that migrate from the subsurface to the air, exposing, mainly the human being to the inhalation of compounds that can offer risk to their health. However this volatilization of this compounds can indicate possible sources of contamination in the subsurface. The agencies of environmental protection, like the EPA (Environmental Protection Agency), in the United States, and the environmental organizations in Brazil, like CETESB - Company of Technology of Environmental Sanitation, has recommended the evaluation of Volatile Organic Compounds - VOC, through the technique called Soil Gas Survey. This technique has been largely used by companies of environmental consulting. It consists on the verification of VOC anomalous concentration in the soil in-situ, by portable analyzers like FID, PID and Catalytic Oxidation, beaconing the investigation work directing the quantity of polls and monitoring wells to the collection of samples of soil and underground water to chemical analyses. This way the present work evaluated the presence of possible vapors in an old abandoned industrial area contaminated by BTEX and organochlorines. This evaluation was made through the Soil Gas Survey technique with the use of the portable analyzer of Catalytic Oxidation and simulated the volatilization of the contaminants presented in the underground water through the mathematical model RBCA - Risk- Based Corrective Action Tool Kit Version 2. The low results of the simulation of the compounds volatilization confirmed the null results in the evaluation campaign of the VOC in the soil through the technique Soil Gas Survey. This results suggest the non capacity of this compound reaching the surface / Mestre Engenharia ambiental. Modelagem geologica. Compostos orgânicos voláteis. Vapor sample. eng Contaminated sites. eng BTEX and organic-chlorine. eng Volatile organic compounds. eng Modelling. eng
132	Avaliação da degradação bacteriana do BTEX (benzeno, tolueno, etilbenzeno, xilenos) na presença de MTBE (metil ter butil eter) e etanol / Bacterial assessment of BTEX (benzene, toluene, ethylbenzene, and xylenes) degradation in the presence of MTBE (methyl tert-butyl ether) and ethanol Sutta Martiarena, Maria Jesus January 2016 (has links) O petróleo é a principal fonte de energia no mundo, mas alguns de seus derivados podem ser prejudiciais à natureza e à saúde. O BTEX, um derivado do petróleo, é usado em combustíveis, sendo estes a maior causa de contaminação ambiental, pois no transporte ou armazenamento destes ocorrem vazamentos que poluem solo e fontes de água. Como alternativas para diminuir a concentração do BTEX no combustível surgiram os aditivos oxigenados, os quais melhoram a qualidade do combustível e reduzem as emissões de monóxido de carbono. Os aditivos mais comuns são o MTBE e o etanol. No entanto, o MTBE é oncogênico e por isso, alguns países o substituem pelo etanol. Porém, o etanol aumenta a solubilidade do BTEX na água, a migração deste no solo, e diminui sua degradação natural. A degradação destes compostos é possível pela ação de microrganismos nativos. Em vista disto, no presente trabalho, bactérias foram isoladas de uma planta de tratamento de águas residuais da indústria petroquímica, com o objetivo de encontrar bactérias tolerantes com capacidade de degradação do BTEX. Os 30 isolados obtidos foram identificados como pertencentes aos gêneros Bacillus, Enterococcus, Staphylococcus, Streptococcus, Pseudomona, Lysinobacterium, Neisseria, Corynobacterium e Leucobacter. Quinze isolados foram tolerantes ao B, T, E, X, e destes, os isolados 16 e 25 pertencentes ao gênero Bacillus, foram testados para a degradação de BTEX, BTEX/MTBE, BTEX/Etanol. A maior porcentagem de degradação foi detectada no tratamento com BTEX seguido por BTEX/MTBE e BTEX/Etanol. O isolado 25 mostrou maior capacidade de degradação dos compostos. / Oil is the main source of energy in the world; nevertheless, some of its derivatives could be harmful to the environment and health. BTEX is a petroleum derivative. It is used in fuels; this one is the main cause of environmental pollution, because during the transport or storage of them there are leaks that pollute the soil and water sources. In order to reduce BTEX concentration in fuel, oxygenated additives emerged; these improve the quality of the fuel and reduce carbon monoxide emissions. The most common additives are MTBE and ethanol. Due to fact that MTBE is oncogenic, some countries replace it with ethanol. Ethanol increases the solubility of BTEX in water, its migration in the ground and decreases its natural degradation. The degradation of harmful compounds by action of native microorganisms has proven to be effective. With this purpose, in the current research, bacteria were isolated from a wastewater treatment plant of petrochemical industry, in order to find tolerant bacteria and with ability to degrade BTEX. The 30 isolates obtained were identified as belonging to the genus Bacillus, Enterococcus, Staphylococcus, Streptococcus, Pseudomonas, Lysinobacterium, Neisseria, Corynobacterium, and Leucobacter. Fifteen isolates were tolerant to B, T, E, X, and out them, isolates 16 and 25 belong to genus Bacillus were tested for degradation of BTEX BTEX / MTBE, BTEX / Ethanol. The highest percentage of degradation was found in the assay with BTEX followed by BTEX / MTBE and BTEX / Ethanol. Isolate 25 showed the highest capacity of degradation. Biorremediação (Saúde Ambiental) Biodegradação ambiental Benzeno Tolueno Xilenos Éter de metil-tert-butil Etanol Tratamento de efluentes industriais Microorganisms Degradation BTEX MTBE Ethanol
133	Stanovení organických sloučenin v dehtu po spalování a zplyňování biomasy / Determination of organic substances in tar formed after biomass combustion and gasification Hájek, Radek January 2015 (has links) Biomass pyrolysis and gasification techniques count among basic technological procedures for its use as a source of energy. As a side-effect, production of tar can be considered. Tar is a complex mixture of various organic compounds and affects negatively both the environment and the facilities where biomass is processed. Within the scope of this master thesis the analysis of tar samples from different materials was performed. As an appropriate analytical method the gas chromatography combined with flame ionization detection (GC-FID) and time-of-flight mass spectrometry (GC-TOF-MS) was chosen. The concentrations of volatile organic compounds known as BTEX, polycyclic aromatic hydrocarbons (PAH) and phenolic compounds were assessed.
134	Assessment of Pollution Levels Resulting from Biomass Gasification Menya, Emmanuel January 2012 (has links) Today the large scale introduction of biomass gasification is hampered by health, safety and environmental issues which present a major barrier in the deployment of this technology. The condensate in particular resulting from producer gas cooling before use in gas engines is highly toxic and carcinogenic which, if not adequately controlled, can lead to detrimental impacts on human health and the environment. The study was therefore aimed at assessment of pollution levels resulting from biomass gasification organic condensates. The study involved assessing the concentration of polycyclic aromatic hydrocarbons (PAHs) and BTEX (i.e. benzene, toluene, ethylbenzene and xylene) in the condensate deemed toxic and carcinogenic, mention their impact on human health and the environment as well as recommend measures aimed at minimizing pollution levels resulting from biomass gasification. The gasifier installation at Makerere University was run in downdraft mode using maize cobs as biomass fuel. The producer gas was cooled using a water cooled condenser connected to the exhaust pipe of the gasifier. The condensate was then transferred into sampling bottles made of opaque glass to minimize photochemical reactions in water samples and preserved in a cooler at 2oC to 6oC until the time for analysis to minimize volatilization and bacterial degradation of the hydrocarbons. The capillary gas chromatography with mass spectrometric detector (CGCMSD) was used to analyze the condensate for the selected hydrocarbons. The procedures involved preparation of PAHs and BTEX standard solutions using standard mixtures and internal standards, calibration of the CGCMSD, extraction of the aromatic hydrocarbons using hexane, performing a surrogate analysis to assess percent recoveries and injecting a 2 µl aliquot of the final solution of each test sample in a CGCMSD for analysis. Identification of targeted hydrocarbons was based on the retention time match and mass spectra match against the calibration standards while quantitation was done by use of internal standards. The average concentration of naphthalene was 204.3 mg/m3, benzene-16.8 mg/m3,toluene-105.5 mg/m3, ethylbenzene-200.9 mg/m3, 1,2-dimethyl benzene-209.5 mg/m3 and 1,3+1,4-dimethyl benzene-790.4 mg/m3. Acenaphthylene, acenaphthene, fluorene, phenanthrene and anthracene were not detected in the condensate by the CGCMSD due to their concentration levels being below the detection limit of the CGCMSD. The concentrations of naphthalene and xylene were considerably high compared to the recommended permissible exposure limits thus posing risks on both human health and the environment. It is therefore important to treat the condensate before disposal to the environment. On the other hand, the concentrations of benzene, toluene and ethylbenzene were below the permissible exposure limit and therefore for this study, the liquid effluent was considered to meet the regulatory standards. The recommendations aimed at minimizing pollution levels during biomass gasification were also discussed. producer gas cooling condensate PAHs BTEX CGCMSD carcinogenic toxic downdraft gasifier Engineering and Technology Teknik och teknologier Mechanical Engineering Maskinteknik Energy Engineering Energiteknik
135	Développement de méthodes d’analyse directe de polluants organiques volatils à l’état de traces dans l’air et les biogaz Badjagbo, Koffi 09 1900 (has links) Il est reconnu que le benzène, le toluène, l’éthylbenzène et les isomères du xylène, composés organiques volatils (COVs) communément désignés BTEX, produisent des effets nocifs sur la santé humaine et sur les végétaux dépendamment de la durée et des niveaux d’exposition. Le benzène en particulier est classé cancérogène et une exposition à des concentrations supérieures à 64 g/m3 de benzène peut être fatale en 5–10 minutes. Par conséquent, la mesure en temps réel des BTEX dans l’air ambiant est essentielle pour détecter rapidement un danger associé à leur émission dans l’air et pour estimer les risques potentiels pour les êtres vivants et pour l’environnement. Dans cette thèse, une méthode d’analyse en temps réel des BTEX dans l’air ambiant a été développée et validée. La méthode est basée sur la technique d’échantillonnage direct de l’air couplée avec la spectrométrie de masse en tandem utilisant une source d’ionisation chimique à pression atmosphérique (APCI-MS/MS directe). La validation analytique a démontré la sensibilité (limite de détection LDM 1–2 μg/m3), la précision (coefficient de variation CV < 10%), l’exactitude (exactitude > 95%) et la sélectivité de la méthode. Des échantillons d’air ambiant provenant d’un site d’enfouissement de déchets industriels et de divers garages d’entretien automobile ont été analysés par la méthode développée. La comparaison des résultats avec ceux obtenus par la technique de chromatographie gazeuse on-line couplée avec un détecteur à ionisation de flamme (GC-FID) a donné des résultats similaires. La capacité de la méthode pour l’évaluation rapide des risques potentiels associés à une exposition aux BTEX a été prouvée à travers une étude de terrain avec analyse de risque pour la santé des travailleurs dans trois garages d’entretien automobile et par des expériences sous atmosphères simulées. Les concentrations mesurées dans l’air ambiant des garages étaient de 8,9–25 µg/m3 pour le benzène, 119–1156 µg/m3 pour le toluène, 9–70 µg/m3 pour l’éthylbenzène et 45–347 µg/m3 pour les xylènes. Une dose quotidienne environnementale totale entre 1,46 10-3 et 2,52 10-3 mg/kg/jour a été déterminée pour le benzène. Le risque de cancer lié à l’exposition environnementale totale au benzène estimé pour les travailleurs étudiés se situait entre 1,1 10-5 et 1,8 10-5. Une nouvelle méthode APCI-MS/MS a été également développée et validée pour l’analyse directe de l’octaméthylcyclotétrasiloxane (D4) et le décaméthylcyclopentasiloxane (D5) dans l’air et les biogaz. Le D4 et le D5 sont des siloxanes cycliques volatils largement utilisés comme solvants dans les processus industriels et les produits de consommation à la place des COVs précurseurs d’ozone troposphérique tels que les BTEX. Leur présence ubiquitaire dans les échantillons d’air ambiant, due à l’utilisation massive, suscite un besoin d’études de toxicité. De telles études requièrent des analyses qualitatives et quantitatives de traces de ces composés. Par ailleurs, la présence de traces de ces substances dans un biogaz entrave son utilisation comme source d’énergie renouvelable en causant des dommages coûteux à l’équipement. L’analyse des siloxanes dans un biogaz s’avère donc essentielle pour déterminer si le biogaz nécessite une purification avant son utilisation pour la production d’énergie. La méthode développée dans cette étude possède une bonne sensibilité (LDM 4–6 μg/m3), une bonne précision (CV < 10%), une bonne exactitude (> 93%) et une grande sélectivité. Il a été également démontré qu’en utilisant cette méthode avec l’hexaméthyl-d18-disiloxane comme étalon interne, la détection et la quantification du D4 et du D5 dans des échantillons réels de biogaz peuvent être accomplies avec une meilleure sensibilité (LDM ~ 2 μg/m3), une grande précision (CV < 5%) et une grande exactitude (> 97%). Une variété d’échantillons de biogaz prélevés au site d’enfouissement sanitaire du Complexe Environnemental de Saint-Michel à Montréal a été analysée avec succès par cette nouvelle méthode. Les concentrations mesurées étaient de 131–1275 µg/m3 pour le D4 et 250–6226 µg/m3 pour le D5. Ces résultats représentent les premières données rapportées dans la littérature sur la concentration des siloxanes D4 et D5 dans les biogaz d’enfouissement en fonction de l’âge des déchets. / It is known that benzene, toluene, ethylbenzene and xylene isomers, volatile organic compounds (VOCs) commonly called BTEX, have toxic health effects on humans and plants depending on duration and levels of exposure. Benzene in particular is classified carcinogenic, and exposure to benzene at concentrations above 64 g/m3 can be fatal within 5–10 minutes. Therefore, real-time monitoring of BTEX in ambient air is essential for the early warning detection associated with their release and in estimating the potential exposure risks to living beings and the environment. In this thesis, a real-time analysis method for BTEX in ambient air was developed and validated. The method is based on the direct-air sampling technique coupled with tandem mass spectrometry using atmospheric pressure chemical ionization (direct APCI-MS/MS). Validation of the method has shown that it is sensitive (limit of detection LOD 1–2 μg/m3), precise (relative standard deviation RSD < 10%), accurate (accuracy > 95%) and selective. Ambient air samples from an industrial waste landfill site and various automobile repair shops were analyzed by the developed method. Comparison of results with those obtained by online gas chromatography coupled with a flame ionization detector (GC-FID) technique exhibited similar results. The capacity of the method for the fast evaluation of potential risks associated with an exposure to BTEX has been demonstrated through a field study with health risk assessment for workers at three automobile repair shops and through experiments under simulated atmospheres. Concentrations measured in the ambient air of the garages were in the ranges of 8.9–25 µg/m3 for benzene, 119–1156 µg/m3 for toluene, 9–70 µg/m3 for ethylbenzene, and 45–347 µg/m3 for xylenes. A total environmental daily dose of 1.46 10-3–2.52 10-3 mg/kg/day was determined for benzene. The estimated cancer risk due to the total environmental exposure to benzene was between 1.1 10-5 and 1.8 10-5 for the workers studied. A novel APCI-MS/MS method was also developed and validated for the direct analysis of octamethylcyclotetrasiloxane (D4) and decamethylcyclopentasiloxane (D5) in air and biogases. D4 and D5 are cyclic volatile siloxanes widely used in industrial processes and consumer products as replacement solvents for the tropospheric ozone forming VOCs, such as BTEX. Their ubiquitous presence in ambient air samples, due to the growing consumption, raises the need for toxicity studies which require qualitative and quantitative trace analysis of these compounds. Furthermore, the presence of trace amounts of these substances in a biogas hampers its use as a source of renewable energy by causing expensive damages to the equipment. Thus, siloxane analysis of the biogas is essential in determining if purification is needed before the use for energy production. The method developed in this study for these aims has good sensitivity (LOD 4–6 μg/m3), good precision (RSD < 10%), good accuracy (> 93%) and high selectivity. It was also shown that by using this method with hexamethyl-d18-disiloxane as an internal standard, detection and quantification of D4 and D5 in real biogas samples can be done with a better sensitivity (LOD ~ 2 μg/m3), high precision (RSD < 5%), and high accuracy (> 97%). Various biogas samples collected from the landfill site of the Complexe Environnemental de Saint-Michel in Montreal have been successfully analyzed by this new method. Concentrations measured were in the ranges of 131–1275 µg/m3 for D4 and 250–6226 µg/m3 for D5. These results represent the first primary-literature-reported data on siloxanes D4 and D5 contents of landfill-derived biogases as a function of the refuse age. Composé organique volatil BTEX Benzène Octaméthylcyclotétrasiloxane D4 Décaméthylcyclopentasiloxane D5 Siloxane Air ambiant Biogaz d’enfouissement APCI-MS/MS Volatile organic compound BTEX Benzene Octamethylcyclotetrasiloxane D4 Decamethylcyclopentasiloxane D5 Siloxane Ambient air Landfill biogas direct Sampling-mass spectrometry APCI-MS/MS
136	Développement de méthodes d’analyse directe de polluants organiques volatils à l’état de traces dans l’air et les biogaz Badjagbo, Koffi 09 1900 (has links) Il est reconnu que le benzène, le toluène, l’éthylbenzène et les isomères du xylène, composés organiques volatils (COVs) communément désignés BTEX, produisent des effets nocifs sur la santé humaine et sur les végétaux dépendamment de la durée et des niveaux d’exposition. Le benzène en particulier est classé cancérogène et une exposition à des concentrations supérieures à 64 g/m3 de benzène peut être fatale en 5–10 minutes. Par conséquent, la mesure en temps réel des BTEX dans l’air ambiant est essentielle pour détecter rapidement un danger associé à leur émission dans l’air et pour estimer les risques potentiels pour les êtres vivants et pour l’environnement. Dans cette thèse, une méthode d’analyse en temps réel des BTEX dans l’air ambiant a été développée et validée. La méthode est basée sur la technique d’échantillonnage direct de l’air couplée avec la spectrométrie de masse en tandem utilisant une source d’ionisation chimique à pression atmosphérique (APCI-MS/MS directe). La validation analytique a démontré la sensibilité (limite de détection LDM 1–2 μg/m3), la précision (coefficient de variation CV < 10%), l’exactitude (exactitude > 95%) et la sélectivité de la méthode. Des échantillons d’air ambiant provenant d’un site d’enfouissement de déchets industriels et de divers garages d’entretien automobile ont été analysés par la méthode développée. La comparaison des résultats avec ceux obtenus par la technique de chromatographie gazeuse on-line couplée avec un détecteur à ionisation de flamme (GC-FID) a donné des résultats similaires. La capacité de la méthode pour l’évaluation rapide des risques potentiels associés à une exposition aux BTEX a été prouvée à travers une étude de terrain avec analyse de risque pour la santé des travailleurs dans trois garages d’entretien automobile et par des expériences sous atmosphères simulées. Les concentrations mesurées dans l’air ambiant des garages étaient de 8,9–25 µg/m3 pour le benzène, 119–1156 µg/m3 pour le toluène, 9–70 µg/m3 pour l’éthylbenzène et 45–347 µg/m3 pour les xylènes. Une dose quotidienne environnementale totale entre 1,46 10-3 et 2,52 10-3 mg/kg/jour a été déterminée pour le benzène. Le risque de cancer lié à l’exposition environnementale totale au benzène estimé pour les travailleurs étudiés se situait entre 1,1 10-5 et 1,8 10-5. Une nouvelle méthode APCI-MS/MS a été également développée et validée pour l’analyse directe de l’octaméthylcyclotétrasiloxane (D4) et le décaméthylcyclopentasiloxane (D5) dans l’air et les biogaz. Le D4 et le D5 sont des siloxanes cycliques volatils largement utilisés comme solvants dans les processus industriels et les produits de consommation à la place des COVs précurseurs d’ozone troposphérique tels que les BTEX. Leur présence ubiquitaire dans les échantillons d’air ambiant, due à l’utilisation massive, suscite un besoin d’études de toxicité. De telles études requièrent des analyses qualitatives et quantitatives de traces de ces composés. Par ailleurs, la présence de traces de ces substances dans un biogaz entrave son utilisation comme source d’énergie renouvelable en causant des dommages coûteux à l’équipement. L’analyse des siloxanes dans un biogaz s’avère donc essentielle pour déterminer si le biogaz nécessite une purification avant son utilisation pour la production d’énergie. La méthode développée dans cette étude possède une bonne sensibilité (LDM 4–6 μg/m3), une bonne précision (CV < 10%), une bonne exactitude (> 93%) et une grande sélectivité. Il a été également démontré qu’en utilisant cette méthode avec l’hexaméthyl-d18-disiloxane comme étalon interne, la détection et la quantification du D4 et du D5 dans des échantillons réels de biogaz peuvent être accomplies avec une meilleure sensibilité (LDM ~ 2 μg/m3), une grande précision (CV < 5%) et une grande exactitude (> 97%). Une variété d’échantillons de biogaz prélevés au site d’enfouissement sanitaire du Complexe Environnemental de Saint-Michel à Montréal a été analysée avec succès par cette nouvelle méthode. Les concentrations mesurées étaient de 131–1275 µg/m3 pour le D4 et 250–6226 µg/m3 pour le D5. Ces résultats représentent les premières données rapportées dans la littérature sur la concentration des siloxanes D4 et D5 dans les biogaz d’enfouissement en fonction de l’âge des déchets. / It is known that benzene, toluene, ethylbenzene and xylene isomers, volatile organic compounds (VOCs) commonly called BTEX, have toxic health effects on humans and plants depending on duration and levels of exposure. Benzene in particular is classified carcinogenic, and exposure to benzene at concentrations above 64 g/m3 can be fatal within 5–10 minutes. Therefore, real-time monitoring of BTEX in ambient air is essential for the early warning detection associated with their release and in estimating the potential exposure risks to living beings and the environment. In this thesis, a real-time analysis method for BTEX in ambient air was developed and validated. The method is based on the direct-air sampling technique coupled with tandem mass spectrometry using atmospheric pressure chemical ionization (direct APCI-MS/MS). Validation of the method has shown that it is sensitive (limit of detection LOD 1–2 μg/m3), precise (relative standard deviation RSD < 10%), accurate (accuracy > 95%) and selective. Ambient air samples from an industrial waste landfill site and various automobile repair shops were analyzed by the developed method. Comparison of results with those obtained by online gas chromatography coupled with a flame ionization detector (GC-FID) technique exhibited similar results. The capacity of the method for the fast evaluation of potential risks associated with an exposure to BTEX has been demonstrated through a field study with health risk assessment for workers at three automobile repair shops and through experiments under simulated atmospheres. Concentrations measured in the ambient air of the garages were in the ranges of 8.9–25 µg/m3 for benzene, 119–1156 µg/m3 for toluene, 9–70 µg/m3 for ethylbenzene, and 45–347 µg/m3 for xylenes. A total environmental daily dose of 1.46 10-3–2.52 10-3 mg/kg/day was determined for benzene. The estimated cancer risk due to the total environmental exposure to benzene was between 1.1 10-5 and 1.8 10-5 for the workers studied. A novel APCI-MS/MS method was also developed and validated for the direct analysis of octamethylcyclotetrasiloxane (D4) and decamethylcyclopentasiloxane (D5) in air and biogases. D4 and D5 are cyclic volatile siloxanes widely used in industrial processes and consumer products as replacement solvents for the tropospheric ozone forming VOCs, such as BTEX. Their ubiquitous presence in ambient air samples, due to the growing consumption, raises the need for toxicity studies which require qualitative and quantitative trace analysis of these compounds. Furthermore, the presence of trace amounts of these substances in a biogas hampers its use as a source of renewable energy by causing expensive damages to the equipment. Thus, siloxane analysis of the biogas is essential in determining if purification is needed before the use for energy production. The method developed in this study for these aims has good sensitivity (LOD 4–6 μg/m3), good precision (RSD < 10%), good accuracy (> 93%) and high selectivity. It was also shown that by using this method with hexamethyl-d18-disiloxane as an internal standard, detection and quantification of D4 and D5 in real biogas samples can be done with a better sensitivity (LOD ~ 2 μg/m3), high precision (RSD < 5%), and high accuracy (> 97%). Various biogas samples collected from the landfill site of the Complexe Environnemental de Saint-Michel in Montreal have been successfully analyzed by this new method. Concentrations measured were in the ranges of 131–1275 µg/m3 for D4 and 250–6226 µg/m3 for D5. These results represent the first primary-literature-reported data on siloxanes D4 and D5 contents of landfill-derived biogases as a function of the refuse age. Composé organique volatil BTEX Benzène Octaméthylcyclotétrasiloxane D4 Décaméthylcyclopentasiloxane D5 Siloxane Air ambiant Biogaz d’enfouissement APCI-MS/MS Volatile organic compound BTEX Benzene Octamethylcyclotetrasiloxane D4 Decamethylcyclopentasiloxane D5 Siloxane Ambient air Landfill biogas direct Sampling-mass spectrometry APCI-MS/MS
137	Flux Measurements of Volatile Organic Compounds from an Urban Tower Platform Park, Chang Hyoun 2010 May 1900 (has links) A tall tower flux measurement setup was established in metropolitan Houston, Texas, to measure trace gas fluxes from both anthropogenic and biogenic emission sources in the urban surface layer. We describe a new relaxed eddy accumulation system combined with a dual-channel gas chromatography - flame ionization detection used for volatile organic compound (VOC) flux measurements in the urban area, focusing on the results of selected anthropogenic VOCs, including benzene, toluene, ethylbenzene and xylenes (BTEX), and biogenic VOCs including isoprene and its oxidation products, methacrolein (MACR) and methyl vinyl ketone (MVK). We present diurnal variations of concentrations and fluxes of BTEX, and isoprene and its oxidation products during summer time (May 22 - July 22, 2008) and winter time (January 1 - February 28). The measured BTEX values exhibited diurnal cycles with a morning peak during weekdays related to rush-hour traffic and additional workday daytime flux maxima for toluene and xylenes in summer time. However, in winter time there was no additional workday daytime peaks due mainly to the different flux footprints between the two seasons. A comparison with different EPA National Emission Inventories (NEI) with our summer time flux data suggests potential underestimates in the NEI by a factor of 3 to 5. The mixing ratios and fluxes of isoprene, MACR and MVK were measured during the same time period in summer 2008. The presented results show that the isoprene was affected by both tail-pipe emission sources during the morning rush hours and biogenic emission sources in daytime. The observed daytime mixing ratios of isoprene were much lower than over forested areas, caused by a comparatively low density of isoprene emitters in the tower's footprint area. The average daytime isoprene flux agreed well with emission rates predicted by a temperature and light only emission model (Guenther et al., 1993). Our investigation of isoprene's oxidation products MACR and MVK showed that both anthropogenic and biogenic emission sources exist for MACR, while MVK was strongly dominated by a biogenic source, likely the isoprene oxidation between the emission and sampling points. relaxed eddy accumulation urban flux measurements gas chromatography GC-FID EPA NEI BTEX benzene toluene ethylbenzene xylene isoprene methacrolein methyl vinyl ketone GIS Geographical information system
138	Stanovení organických sloučenin v dehtu / Determination of organic compounds in the tar Magdechová, Andrea January 2011 (has links) The diploma thesis deals with determination of organic compounds in the tar. It is focussed on polycyclic aromatic hydrocarbons, BTEX and n-alkanes. The tar samples were collected by Faculty of Mechanical Engineering BUT Brno during two days and under diferent conditions of biomass gasification. The samples were filtrated and refined using column chromatography on silicagel sorbent. Gas chromatography with mass detection was chosen to determine polycyclic aromatic hydrocarbons and gas chromatography with flame ionisation detection was chosen to determine BTEX and n-alkanes.
139	Volatile organic compounds(VOC's) analysis from Cape Town haze ll study Chiloane, Kgaugelo Euphinia 09 November 2006 (has links) Student Number: 9503012G Master of Science. School of Geography, Archaeology and Environmental Studies / A brown haze which builds-up over Cape Town under calm and cold weather conditions causes public concern. The brown haze is thought to be due to the gaseous and particulate emissions from the city, industries, traffic and townships in the Cape Town region. Volatile organic carbon (VOCs) compounds are an important component of the haze layer particularly because of their reactivity. VOCs play an important role in the carbon budget and radiation balance, regional oxidant balance, and in the distribution of ozone and other reactive gases, both at the regional and global scale. In this study the variation in ambient VOC concentrations during brown and non-brown haze days over Cape Town during July and August 2003 were characterised. Ambient air samples were collected in evacuated stainless steel canistes from the South African Weather Service (SAWS) research aircraft (Aerocommander, ZS-JRB) and later analysed by gas chromotography equipped with a flame ionisation detector (GC-FID). Benzene, toluene, ethylbenzene and xylene (BTEX) were the specific VOCs targeted for this study. Comparable meteorology data was also collected to determine the effects of wind field and atmospheric stability on BTEX concentrations. Volatile organic carbon (VOC) Cape Town Carbon budget Radiation balance Regional oxidant balance Reactive gases South African Weather Service Gas chromatography Flame ionisation detector (GC-FID) Benzene Toluene Ethylbenzene Xylene (BTEX)

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