Abstract
Condensate banking is a common problem in tight gas reservoirs because it diminishes the gas relative permeability and reduces the gas production rate significantly. CO2 injection is a common and very effective solution to mitigate the condensate damage around the borehole in tight gas reservoirs. The problem with CO2 injection is that it is a temporary solution and has to be repeated frequently in the field in addition to the supply limitations of CO2 in some areas. In addition, the infrastructure required at the surface to handle CO2 injection makes it expensive to apply CO2 injection for condensate removal. In this paper, a new permanent technique is introduced to remove the condensate by using a thermochemical technique. Two chemicals will be used to generate in situ CO2, nitrogen, steam, heat, and pressure. The reaction of the two chemicals downhole can be triggered either by the reservoir temperature or a chemical activator. Two chemicals will start reacting and produce all the mentioned reaction products after 24 h of mixing and injection. In addition, the reaction can be triggered by a chemical activator and this will shorten the time of reaction. Coreflooding experiments were carried out using actual condensate samples from one of the gas fields. Tight sandstone cores of 0.9 mD permeability were used. The results of this study showed that the thermochemical reaction products removed the condensate and reduced its viscosity due to the high temperature and the generated gases. The novelty in this paper is the creation of micro-fractures in the tight rock sample due to the in-situ generation of heat and pressure. These micro-fractures reduced the capillary forces that hold the condensate and enhanced the rock relative permeability. The creation of micro-fractures and in turn the reduction of the capillary forces can be considered as permanent condensate removal.
Highlights
Gas reservoirs are playing a significant rule in the energy supply due to its abundance, low price, and low emission of greenhouse gases compared to crude oil [1]
This paper introduces a new method for removing the condensate banking from tight formations, by utilizing chemical injection
Coreflooding tests were carried out to study the effectiveness of thermochemical treatment in Coreflooding tests were carried out to study the effectiveness of thermochemical treatment in recovering the condensate liquid
Summary
Gas reservoirs are playing a significant rule in the energy supply due to its abundance, low price, and low emission of greenhouse gases compared to crude oil [1]. Are extensively applied to remove the accumulated condensate and improve the reservoir The ultimate objective of these treatments is to create more favorable flow conditions by either deliverability [6,7]. Hydraulic fracturing isfractures applied reduce to generate conductive paths between reservoir condensate accumulation. The fracture treatment resulted in enhancing depending on several factors formation properties, and injected of theistotal gas production from including; tight carbonate reservoirs by hydrocarbon three folds composition,. Carbon dioxide injection is a common and very effective solution for condensate removal in tight gas reservoirs [18]. Several experiments were conducted including coreflooding tests and pressure-volume-temperature (PVT) measurements They concluded that, injection of carbon dioxide is recommended over water flooding for removing the condensate damage and improving the gas deliverability. The generated fractures showed significant improvements in the gas relative permeability and capillary forces
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