From oil field to geothermal reservoir: assessment for geothermal utilization of two regionally extensive Devonian carbonate aquifers in Alberta, Canada

Weydt, Leandra M.; Heldmann, Claus-Dieter; Machel, Hans G.; Sass, Ingo

doi:10.5194/se-9-953-2018

Cited by 17 publications

(9 citation statements)

References 55 publications

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“…Electrical power from geothermal is between single decimals of MW electrical and up to 3 MW electrical (see our calculations in Table A1) assuming a maximum flow rates of 80 kg/s. However, horizontal wells in target horizons promise to increase potential production rates that could make power production more viable in areas of suitable temperatures as in the ongoing DEEP project [45][46][47][48].…”

Section: Discussionmentioning

confidence: 99%

Deep Geothermal Heating Potential for the Communities of the Western Canadian Sedimentary Basin

Majorowicz

Grasby

2021

Energies

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We summarize the feasibility of using geothermal energy from the Western Canada Sedimentary Basin (WCSB) to support communities with populations >3000 people, including those in northeastern British Columbia, southwestern part of Northwest Territories (NWT), southern Saskatchewan, and southeastern Manitoba, along with previously studied communities in Alberta. The geothermal energy potential of the WCSB is largely determined by the basin’s geometry; the sediments start at 0 m thickness adjacent to the Canadian shield in the east and thicken to >6 km to the west, and over 3 km in the Williston sub-basin to the south. Direct heat use is most promising in the western and southern parts of the WCSB where sediment thickness exceeds 2–3 km. Geothermal potential is also dependent on the local geothermal gradient. Aquifers suitable for heating systems occur in western-northwestern Alberta, northeastern British Columbia, and southwestern Saskatchewan. Electrical power production is limited to the deepest parts of the WCSB, where aquifers >120 °C and fluid production rates >80 kg/s occur (southwestern Northwest Territories, northwestern Alberta, northeastern British Columbia, and southeastern Saskatchewan. For the western regions with the thickest sediments, the foreland basin east of the Rocky Mountains, estimates indicate that geothermal power up to 2 MWel. (electrical), and up to 10 times higher for heating in MWth. (thermal), are possible.

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Section: Discussionmentioning

confidence: 99%

Deep Geothermal Heating Potential for the Communities of the Western Canadian Sedimentary Basin

Majorowicz

Grasby

2021

Energies

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“…Gas pycnometry (determination of the effective porosity, which is an approximation of the total porosity, due to He diffusion) was conducted on all samples according to the recommendations of Micromeritics [26] as described in Weydt et al [27] with the two-chamber systems AccuPyc 1330, AccuPyc II 1340 and CorePyc 1360 (Micromeritics, Germany) using He. The bulk volume was calculated from the geometry of the cylindrical cores.…”

Section: Petrophysical Methodsmentioning

confidence: 99%

“…The pressure difference was set between up to 1000 mbar (samples with permeabilities in the range of 10 −17 m 2 ) and only 50 mbar (permeabilities below 10 −14 m 2 ). Further information about the method is provided by Weydt et al [27]. Since the sample axis was parallel to the vein, the measured permeability was a combined vein and matrix permeability and the permeability of the whole sample was highly anisotropic.…”

Section: Petrophysical Methodsmentioning

confidence: 99%

Lab-Scale Permeability Enhancement by Chemical Treatment in Fractured Granite (Cornubian Batholith) for the United Downs Deep Geothermal Power Project, Cornwall (UK)

2022

Self Cite

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A hydrothermal doublet system was drilled in a fault-related granitic reservoir in Cornwall. It targets the Porthtowan Fault Zone (PTF), which transects the Carnmenellis granite, one of the onshore plutons of the Cornubian Batholith in SW England. At 5058 m depth (TVD, 5275 m MD) up to 190 °C were reached in the dedicated production well. The injection well is aligned vertically above the production well and reaches a depth of 2393 m MD. As part of the design process for potential chemical stimulation of the open-hole sections of the hydrothermal doublet, lab-scale acidification experiments were performed on outcrop analogue samples from the Cornubian Batholith, which include mineralised veins. The experimental setup comprised autoclave experiments on sample powder and plugs, and core flooding tests on sample plugs to investigate to what degree the permeability of natural and artificial (saw-cut) fractures can be enhanced. All samples were petrologically and petrophysically analysed before and after the acidification experiments to track all changes resulting from the acidification. Based on the comparison of the mineralogical composition of the OAS samples with the drill cuttings from the production well, the results can be transferred to the hydrothermally altered zones around the faults and fractures of the PTF. Core Flooding Tests and Autoclave Experiments result in permeability enhancement factors of 4 to >20 and 0.1 to 40, respectively. Mineral reprecipitation can be avoided in the stimulated samples by sufficient post-flushing.

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“…Fig. 1 shows a structure diagram of an open geothermal single-well system with lateral wellbores on the production line, which was developed on the basis of works [3,6,8]. The heat-transfer medium, heated to bed temperature, is taken from the bed 1, and with a temperature close to this, it enters to the heat exchanger 5.…”

Section: Introductionmentioning

confidence: 99%

Phenomenological model of an open-type geothermal system on the basis of oil-and-gas well

Fyk

Biletsky

2020

E3S Web Conf.

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This paper relates to mining-well technologies. A theoretical and methodological approach is proposed to modeling geothermal well systems, which includes the development of: principal technological scheme of a geothermal system; schemes of transformation and movement of energy and a heat-transfer medium; the geothermal system phenomenological model; analysis of subprocesses and obtaining their mathematical models and, on this basis, the mathematical model of the geothermal model as a whole. An example of an advanced open-type geothermal well system is studied, which is based on the oil-and-gas well with one loop of circulation and the parallel connection of heat pumps at characteristic points of the system. The subprocesses of the developed phenomenological model are analysed and the characteristic features of their mathematical description are revealed; in particular, it is substantiated that the redistribution of heat power entering from a fluid-saturated bed is substantially dependent on the lateral wellbore geometry. Another important feature is to model the downhole heat pump and the modes in the scheme as a whole, which is based on the mass flow rate of a heat-transfer medium in its circulation loop. A generalized formula is presented for the heat power of the analysed advanced geothermal well system.

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From oil field to geothermal reservoir: assessment for geothermal utilization of two regionally extensive Devonian carbonate aquifers in Alberta, Canada

Cited by 17 publications

References 55 publications

Deep Geothermal Heating Potential for the Communities of the Western Canadian Sedimentary Basin

Deep Geothermal Heating Potential for the Communities of the Western Canadian Sedimentary Basin

Lab-Scale Permeability Enhancement by Chemical Treatment in Fractured Granite (Cornubian Batholith) for the United Downs Deep Geothermal Power Project, Cornwall (UK)

Phenomenological model of an open-type geothermal system on the basis of oil-and-gas well

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