RDV■(dynamic vasoactive reactor)chemical technology represents a disruptive innovation operating under both surface and downhole conditions,producing irreversible and in situ adaptable effects.It has demonstrated tra...RDV■(dynamic vasoactive reactor)chemical technology represents a disruptive innovation operating under both surface and downhole conditions,producing irreversible and in situ adaptable effects.It has demonstrated transformative capacity across crude oils of various API gravities,with notable impact on extra-heavy crudes and bitumens,through a mechanism based on targeted proton donation that induces selective protonation of polar structures,generating transient carbocations that catalyze molecular fragmentation.This work presents a comprehensive analysis of the effects of RDV-DMG001■treatment(currently named RDV-01L■)on bitumen samples from the Primrose field,Alberta,Canada,using capillary chromatography,SARA analysis,and rheological evaluation,complemented with comparative data on prior applications of RDV-01L■in extra-heavy crudes from Venezuela(Boscán and El Salto).Results for Primrose bitumen show an 85%reduction in viscosity(from 500,000 to 75,000 cP),an increase in API gravity from 8.5 to 15.0(+76.4%),and molecular redistribution toward medium-chain hydrocarbons(C_(13)-C_(16)),with increases in molar and mass fractions up to 39.1%and 62.3%,respectively.SARA analysis confirmed fragmentation of asphaltenes(2.0%mass reduction)and a 5.8%increase in resins,improving colloidal stability and lowering precipitation risk.These changes align with RDV■’s mechanism of action based on carbocation generation.Notably,in field conditions-which are more dynamic and energetically favorable-RDV■treatment efficacy tends to exceed laboratory results,due to synergy among temperature,pressure,and fluid flow gradients which accelerate and enhance protonation and molecular fragmentation.Validated in contexts of advanced chemical transformation(Venezuela,Canada),the technology enables substantial improvements in fluidity,transport,processing,and recovery,with significant potential for annual cost savings in extraction and processing.This study positions RDV■as a disruptive,irreversible,and in situ adaptable chemical solution superior to conventional technologies such as surfactants,nanocatalysts,or aquathermolysis.RDV■is a quantum-impact chemical technology operating via molecular protonation reactions and controlled carbocation formation.The term“quantum”is used here as a conceptual analogy to describe the magnitude and specificity of the molecular reconfiguration induced by RDV■,without asserting direct experimental evidence of quantum reactivity.展开更多
Dual-well steam assisted gravity drainage(SAGD) has significant potential for extra-heavy oil recovery.China is conducting two dual-well SAGD pilot projects in the Fengcheng extra-heavy oil reservoir.Quick,direct pred...Dual-well steam assisted gravity drainage(SAGD) has significant potential for extra-heavy oil recovery.China is conducting two dual-well SAGD pilot projects in the Fengcheng extra-heavy oil reservoir.Quick,direct predictions of the oil production rate by algebraic models rather than complex numerical models are of great importance for designing and adjusting the SAGD operations.A low-pressure scaled physical simulation was previously used to develop two separate theoretical models corresponding to the two different growth stages observed in the SAGD steam chambers,which are the steam chamber rising stage and the steam chamber spreading stage.A high-pressure scaled model experiment is presented here for one dual-well SAGD pattern to further improve the prediction models to reasonably predict oil production rates for full production.Parameters that significantly affect the oil recovery during SAGD were scaled for the model size based on the reservoir characteristics of the Fengcheng reservoir in China.Experimental results show the relationship between the evolution of the steam chamber and the oil production rate during the entire production stage.High-pressure scaled model test was used to improve the gravity drainage models by modifying empirical factors for the rising model and the depletion model.A new division of the SAGD production regime was developed based on the relationship between the oil production rate and the evolution of steam chamber.A method was developed to couple the rising and depletion models to predict oil production rates during the SAGD production,especially during the transition period.The method was validated with experiment data and field data from the literature.The model was then used to predict the oil production rate in the Fengcheng reservoir in China and the Athabasca reservoir in Canada.展开更多
Most of the studies regarding the formation and stability of emulsions focus on the conditioning and management of crude oil on surface facilities.Since a great deal of the crude oil produced is in the form of stable ...Most of the studies regarding the formation and stability of emulsions focus on the conditioning and management of crude oil on surface facilities.Since a great deal of the crude oil produced is in the form of stable emulsions,it is often claimed that these emulsions are formed through chokes and other flow constrictions in oil field equipment.However,emulsions are produced in wells,which not only lack these constrictions but also are produced at low flow rates,demonstrating the fact that emulsions can be formed within the well itself.The present work reviews the literature regarding the formation and properties of heavy and extra-heavy oil emulsions in naturally fractured porous media due to the current relevance that these types of crude oil exploitation take,satisfying the hydrocarbon energy demand.Moreover,emulsions have received more attention recently since they can be formed in-situ and improve oil recovery.To understand the flow mechanics of emulsions in porous media,different models to describe their transportation are presented.Finally,the formation of emulsions in the reservoir for enhanced oil recovery purposes,including the use of nanoparticlestabilized emulsions is discussed.展开更多
文摘RDV■(dynamic vasoactive reactor)chemical technology represents a disruptive innovation operating under both surface and downhole conditions,producing irreversible and in situ adaptable effects.It has demonstrated transformative capacity across crude oils of various API gravities,with notable impact on extra-heavy crudes and bitumens,through a mechanism based on targeted proton donation that induces selective protonation of polar structures,generating transient carbocations that catalyze molecular fragmentation.This work presents a comprehensive analysis of the effects of RDV-DMG001■treatment(currently named RDV-01L■)on bitumen samples from the Primrose field,Alberta,Canada,using capillary chromatography,SARA analysis,and rheological evaluation,complemented with comparative data on prior applications of RDV-01L■in extra-heavy crudes from Venezuela(Boscán and El Salto).Results for Primrose bitumen show an 85%reduction in viscosity(from 500,000 to 75,000 cP),an increase in API gravity from 8.5 to 15.0(+76.4%),and molecular redistribution toward medium-chain hydrocarbons(C_(13)-C_(16)),with increases in molar and mass fractions up to 39.1%and 62.3%,respectively.SARA analysis confirmed fragmentation of asphaltenes(2.0%mass reduction)and a 5.8%increase in resins,improving colloidal stability and lowering precipitation risk.These changes align with RDV■’s mechanism of action based on carbocation generation.Notably,in field conditions-which are more dynamic and energetically favorable-RDV■treatment efficacy tends to exceed laboratory results,due to synergy among temperature,pressure,and fluid flow gradients which accelerate and enhance protonation and molecular fragmentation.Validated in contexts of advanced chemical transformation(Venezuela,Canada),the technology enables substantial improvements in fluidity,transport,processing,and recovery,with significant potential for annual cost savings in extraction and processing.This study positions RDV■as a disruptive,irreversible,and in situ adaptable chemical solution superior to conventional technologies such as surfactants,nanocatalysts,or aquathermolysis.RDV■is a quantum-impact chemical technology operating via molecular protonation reactions and controlled carbocation formation.The term“quantum”is used here as a conceptual analogy to describe the magnitude and specificity of the molecular reconfiguration induced by RDV■,without asserting direct experimental evidence of quantum reactivity.
基金supported by the National Key Science and Technology Project of China (Grant No. 2011ZX05012)
文摘Dual-well steam assisted gravity drainage(SAGD) has significant potential for extra-heavy oil recovery.China is conducting two dual-well SAGD pilot projects in the Fengcheng extra-heavy oil reservoir.Quick,direct predictions of the oil production rate by algebraic models rather than complex numerical models are of great importance for designing and adjusting the SAGD operations.A low-pressure scaled physical simulation was previously used to develop two separate theoretical models corresponding to the two different growth stages observed in the SAGD steam chambers,which are the steam chamber rising stage and the steam chamber spreading stage.A high-pressure scaled model experiment is presented here for one dual-well SAGD pattern to further improve the prediction models to reasonably predict oil production rates for full production.Parameters that significantly affect the oil recovery during SAGD were scaled for the model size based on the reservoir characteristics of the Fengcheng reservoir in China.Experimental results show the relationship between the evolution of the steam chamber and the oil production rate during the entire production stage.High-pressure scaled model test was used to improve the gravity drainage models by modifying empirical factors for the rising model and the depletion model.A new division of the SAGD production regime was developed based on the relationship between the oil production rate and the evolution of steam chamber.A method was developed to couple the rising and depletion models to predict oil production rates during the SAGD production,especially during the transition period.The method was validated with experiment data and field data from the literature.The model was then used to predict the oil production rate in the Fengcheng reservoir in China and the Athabasca reservoir in Canada.
基金The authors thank funding from PAPIIT TA100917 and CONACYT 280816
文摘Most of the studies regarding the formation and stability of emulsions focus on the conditioning and management of crude oil on surface facilities.Since a great deal of the crude oil produced is in the form of stable emulsions,it is often claimed that these emulsions are formed through chokes and other flow constrictions in oil field equipment.However,emulsions are produced in wells,which not only lack these constrictions but also are produced at low flow rates,demonstrating the fact that emulsions can be formed within the well itself.The present work reviews the literature regarding the formation and properties of heavy and extra-heavy oil emulsions in naturally fractured porous media due to the current relevance that these types of crude oil exploitation take,satisfying the hydrocarbon energy demand.Moreover,emulsions have received more attention recently since they can be formed in-situ and improve oil recovery.To understand the flow mechanics of emulsions in porous media,different models to describe their transportation are presented.Finally,the formation of emulsions in the reservoir for enhanced oil recovery purposes,including the use of nanoparticlestabilized emulsions is discussed.
