The Experts below are selected from a list of 279 Experts worldwide ranked by ideXlab platform
Laura A Pellegrini - One of the best experts on this subject based on the ideXlab platform.
-
Thermodynamic Method for the prediction of solid CO2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO2 capture processes based on CO2 freeze-out or where the formation of solid CO2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid-liquid-vapor equilibrium of CO2 mixtures with n-alkanes or H2S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results. © 2013 The Institution of Chemical Engineers.
-
Thermodynamic Method for the prediction of solid co2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:Abstract The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO 2 capture processes based on CO 2 freeze-out or where the formation of solid CO 2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO 2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO 2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO 2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid–liquid–vapor equilibrium of CO 2 mixtures with n -alkanes or H 2 S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results.
Giorgia De Guido - One of the best experts on this subject based on the ideXlab platform.
-
Thermodynamic Method for the prediction of solid CO2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO2 capture processes based on CO2 freeze-out or where the formation of solid CO2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid-liquid-vapor equilibrium of CO2 mixtures with n-alkanes or H2S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results. © 2013 The Institution of Chemical Engineers.
-
Thermodynamic Method for the prediction of solid co2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:Abstract The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO 2 capture processes based on CO 2 freeze-out or where the formation of solid CO 2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO 2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO 2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO 2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid–liquid–vapor equilibrium of CO 2 mixtures with n -alkanes or H 2 S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results.
Stefano Langè - One of the best experts on this subject based on the ideXlab platform.
-
Thermodynamic Method for the prediction of solid CO2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO2 capture processes based on CO2 freeze-out or where the formation of solid CO2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid-liquid-vapor equilibrium of CO2 mixtures with n-alkanes or H2S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results. © 2013 The Institution of Chemical Engineers.
-
Thermodynamic Method for the prediction of solid co2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:Abstract The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO 2 capture processes based on CO 2 freeze-out or where the formation of solid CO 2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO 2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO 2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO 2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid–liquid–vapor equilibrium of CO 2 mixtures with n -alkanes or H 2 S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results.
Stefania Moioli - One of the best experts on this subject based on the ideXlab platform.
-
Thermodynamic Method for the prediction of solid CO2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO2 capture processes based on CO2 freeze-out or where the formation of solid CO2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid-liquid-vapor equilibrium of CO2 mixtures with n-alkanes or H2S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results. © 2013 The Institution of Chemical Engineers.
-
Thermodynamic Method for the prediction of solid co2 formation from multicomponent mixtures
Process Safety and Environmental Protection, 2014Co-Authors: Giorgia De Guido, Stefano Langè, Stefania Moioli, Laura A PellegriniAbstract:Abstract The increase in GHG concentration has a direct effect on global climate conditions. Among the possible technologies to mitigate GHG emissions, CCS is being accepted to gain emission reduction. Such technology also involves cryogenic CO 2 capture processes based on CO 2 freeze-out or where the formation of solid CO 2 must be avoided. Captured CO 2 is usually transported in pipelines for the reinjection. The risk associated to the release of CO 2 is due to the changing temperatures and pressures the system may experience, which can lead to the deposition of solid CO 2 where it must be avoided. Prolonged exposure to dry ice can cause severe skin damage and its resublimation could pose a danger of hypercapnia. It is, thus, necessary to build up a tool able to predict the conditions in which CO 2 can freeze-out. A Thermodynamic Methodology based on cubic EoSs has been developed which is able to predict solid–liquid–vapor equilibrium of CO 2 mixtures with n -alkanes or H 2 S which are usually found in equipment for acidic gas, mainly natural gas, treatment. The focus is a detailed analysis of the Method performances when more than two components are present since, for such a case, literature does not provide significant modeling results.
J H Li - One of the best experts on this subject based on the ideXlab platform.
-
proposed Thermodynamic Method to predict the glass formation of the ternary transition metal systems
Physical Chemistry Chemical Physics, 2009Co-Authors: Tao Wang, J H LiAbstract:By considering the energetic competition between the crystalline solid solution and glass phase, a Thermodynamic Method is proposed to predict/determine the glass forming range of a ternary metal system and in terms of the dynamics, the parameter γABC* is further defined to search for a proper alloy with superior glass forming ability in the system. 10 more ternary/binary metal systems, e.g. the Cu–Zr–Ti and Cu–Hf–Ti systems, were studied and the predicted alloys of superior glass forming ability match well with those reported from experimental observations.
