Your search keyword '"Thaler, Jan"' showing total 3 results

1. Characterizing electrical properties and permeability changes of hydrate bearing sediments using ERT data.

Author

Priegnitz, Mike, Thaler, Jan, Spangenberg, Erik, Schicks, Judith M., Schrötter, Jörg, and Abendroth, Sven

Subjects

*PERMEABILITY, *SEDIMENTS, *HYDRATES, *ELECTRICAL resistivity, *TOMOGRAPHY

Abstract

A LArge Reservoir Simulator (LARS) was equipped with an electrical resistivity tomography (ERT) array to monitor hydrate formation and dissociation experiments. During two hydrate formation experiments reaching 90 per cent bulk hydrate saturation, frequent measurements of the electrical properties within the sediment sample were performed. Subsequently, several common mixing rules, including two different interpretations of Archie's law, were tested to convert the obtained distribution of the electrical resistivity into the spatial distribution of local hydrate saturation. It turned out that the best results estimating values of local hydrate saturation were obtained using the Archievar-phi approach where the increasing hydrate phase is interpreted as part of the sediment grain framework reducing the sample's porosity. These values of local hydrate saturation were used to determine local permeabilities by applying the Carman-Kozeny relation. The formed hydrates were dissociated via depressurization. The decomposition onset as well as areas featuring hydrates and free gas were inferred from the ERT results. Supplemental consideration of temperature and pressure data granted information on discrete areas of hydrate dissociation. [ABSTRACT FROM AUTHOR]

Published

2015

2. A cylindrical electrical resistivity tomography array for three-dimensional monitoring of hydrate formation and dissociation.

Author

Priegnitz, Mike, Thaler, Jan, Spangenberg, Erik, Rücker, Carsten, and Schicks, Judith M.

Subjects

*SIMULATION methods & models, *GAS hydrates, *ELECTRICAL resistivity, *TOMOGRAPHY, *DISSOCIATION (Chemistry)

Abstract

The LArge Reservoir Simulator (LARS) was developed to investigate various processes during gas hydrate formation and dissociation under simulated in situ conditions of relatively high pressure and low temperature (close to natural conditions). To monitor the spatial hydrate distribution during hydrate formation and the mobility of the free gas phase generated during hydrate dissociation, a cylindrical Electrical Resistivity Tomography (ERT) array was implemented into LARS. The ERT contains 375 electrodes, arranged in 25 circular rings featuring 15 electrodes each. The electrodes were attached to a neoprene jacket surrounding the sediment sample. Circular (2D) dipole-dipole measurements are performed which can be extended with additional 3D cross measurements to provide supplemental data. The data quality is satisfactory, with the mean standard deviation due to permanent background noise and data scattering found to be in the order of 2.12%. The measured data are processed using the inversion software tool Boundless Electrical Resistivity Tomography to solve the inverse problem. Here, we use data recorded in LARS to demonstrate the data quality, sensitivity, and spatial resolution that can be obtained with this ERT array. [ABSTRACT FROM AUTHOR]

Published

2013

3. Development, test, and evaluation of exploitation technologies for the application of gas production from natural gas hydrate reservoirs and their potential application in the Danube Delta, Black Sea.

Author

Schicks, Judith M., Haeckel, Matthias, Janicki, Georg, Spangenberg, Erik, Thaler, Jan, Giese, Ronny, Strauch, Bettina, Heeschen, Katja, Priegnitz, Mike, Luzi-Helbing, Manja, Deusner, Christian, Kossel, Elke, Bigalke, Nikolaus, Schlüter, Stefan, Hennig, Torsten, Deerberg, Görge, and Wallmann, Klaus

Subjects

*GAS reservoirs, *NATURAL gas, *NATURAL gas production, *METHANE hydrates, *GAS hydrates

Abstract

One important scientific objective of the national research project SUGAR – Submarine Gas Hydrate Reservoirs was the development, improvement, and test of innovative concepts for the production of methane from natural gas hydrate reservoirs. Therefore, different production methods, such as the thermal stimulation using in situ combustion, the chemical stimulation via injection of CO 2 as a gaseous, liquid or supercritical phase and depressurization were tested alone or in combination at different scales. In the laboratory experiments these ranged from pore and hydrate grain scale to 425-L reactor volume, whereas numerical models were applied to describe the related processes from molecular to reservoir scale. In addition, the numerical simulations also evaluated the feasibility and efficiency of the application of these methods in selected areas, such as the Danube Paleodelta in the Black Sea, addressing the two dominant methane hydrate reservoir settings, buried channel-levee and turbidite systems. It turned out, that the injection of CO 2 or a CO 2 –N 2 gas mixture is not applicable for the Danube Paleodelta in the Black Sea, because the local pressure and temperature conditions are too close to the equilibrium conditions of both, the CO 2 hydrate and a CO 2 –N 2 mixed hydrate stability fields. Experiments using thermal stimulation and depressurization showed promising results but also some issues, such as sufficient heat transfer. In summary it can be said that the applicability and efficiency of each method has to be proven for each specific hydrate reservoir conditions. Based on the results obtained by numerical simulations the most promising and safe method for the production of CH 4 from hydrate bearing sediments in the Danube Paleodelta would be the depressurization technique. This study summarizes the main experimental and modeling results. • The SUGAR project has developed and tested various methods for gas production from marine gas hydrates from micro to field scale. • Numerical simulations improved the understanding of processes on molecular to reservoir scale. • Depressurization is a promising technology for exploiting gas hydrate deposits in the Danube Delta. • The injection of CO 2 or CO 2 –N 2 is not a suitable method for the exploitation of gas hydrate deposits in the Danube Delta. [ABSTRACT FROM AUTHOR]

Published

2020