Harmonic Pulse Testing for Well Monitoring: Application to a Fractured Geothermal Reservoir

Borello, Eloisa Salina; Fokker, P.A.; Viberti, Dario; Verga, Francesca; Hofmann, Hannes; Meier, Peter; Min, Ki‐Bok; Yoon, Kern Shin; Zimmermann, Günter

doi:10.1029/2018wr024029

Cited by 17 publications

(14 citation statements)

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“…Field studies employing oscillatory flow interference testing described in the literature use multiple approaches to generate the pressure stimulation. One approach uses a pump in a water storage tank at the surface and another in the borehole to alternate pumping and injection flow rates in a periodic manner, creating a square signal centered around either a flow rate of zero or a constant background pumping rate (Rasmussen et al 2003 ; Renner and Messar 2006 ; Salina Borello et al 2019 ). Using this approach, the amplitude of the observation signal is controlled by the chosen pumping and injection flow rates.…”

Section: Introductionmentioning

confidence: 99%

Aquifer Characterization and Uncertainty in Multi‐Frequency Oscillatory Flow Tests: Approach and Insights

Patterson¹,

Cardiff

2021

Groundwater

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Characterizing aquifer properties and their associated uncertainty remains a fundamental challenge in hydrogeology. Recent studies demonstrate the use of oscillatory flow interference testing to characterize effective aquifer flow properties. These characterization efforts relate the relative amplitude and phase of an observation signal with a single frequency component to aquifer diffusivity and transmissivity. Here, we present a generalized workflow that relates extracted Fourier coefficients for observation signals with single and multiple frequency components to aquifer flow properties and their associated uncertainty. Through synthetic analytical modeling we show that multi-frequency oscillatory flow interference testing adds information that improves inversion performance and decreases parameter uncertainty. We show increased observation signal length, sampling frequency, and pressure sensor accuracy all produce decreased parameter uncertainty. This work represents the first attempt we are aware of to quantify effective aquifer parameters and their associated uncertainty using multi-frequency oscillatory flow interference testing.

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Section: Introductionmentioning

confidence: 99%

Aquifer Characterization and Uncertainty in Multi‐Frequency Oscillatory Flow Tests: Approach and Insights

Patterson¹,

Cardiff

2021

Groundwater

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“…Indirect hydromechanical coupling effects, which tend to be most important in fractured rocks, involve changes in the hydraulic or mechanical properties of the system in response to variations in applied stress or fluid pressure (e.g., stress‐dependent effective permeability and stiffness). In the context of the hydraulic characterization of fractured rocks, hydromechanical coupling effects, which depend on the structural, hydraulic, and elastic properties of the fractures and their embedding background, can range from almost imperceptible pressure variations to induced seismicity due to pressure‐induced fracturing or frictional failure along preexisting faults (e.g., Rutqvist & Stephansson, 2003; Salina Borello et al., 2019). Understanding and recognizing the role of hydromechanical coupling for fluid flow through fractures is, thus, crucial for improving the currently employed modeling and interpretation methods, and for reducing uncertainties in the analysis of experimental data related to fluid‐driven processes in fractured media (e.g., Ghassemi, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Time lapse monitoring is greatly facilitated by the periodic nature of the induced flow rates, which allows for the isolation of the probed formation's response from other hydraulic processes. Periodic pumping can even be combined with other injection operations such as, for example, hydraulic stimulation experiments and be used to monitor changes in the hydraulic response at specific oscillation periods (Salina Borello et al., 2019). The periodicity is an important characteristic of these methods, as varying the oscillation period, and thus the penetration depth L d of the pressure diffusion process (

{L}_{d}\sim \sqrt{DT}

, with D and T being the diffusivity of the probed medium and the period of the PHT, respectively), allows for the assessment of the hydraulic heterogeneity in the probed formation (e.g., Cardiff et al., 2013; Fokker et al., 2013).…”

Section: Introductionmentioning

confidence: 99%

Period‐ and Pressure‐Dependent Hydraulic Properties of a Fractured Granite Inferred From Periodic Pumping Tests

Barbosa,

Jiménez Martínez,

Gholizadeh Doonechaly

et al. 2023

JGR Solid Earth

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Fractures can greatly impact fluid flow and pore pressure distribution in the upper crust. By conducting borehole hydraulic experiments, we can determine the ability of fractures to transport fluids and affect pressure diffusion under in situ conditions. We performed a series of periodic hydraulic tests in a borehole at the Bedretto Underground Laboratory for Geosciences and Geoenergies (Switzerland). We investigated the period‐ and pressure‐dependent response of a fractured granite by controlling the flow rate of harmonic and non‐harmonic oscillations, covering a wide range of periods as well as mean‐ and amplitude‐pressure values. By analyzing the phase and amplitude relation between the flow rate and fluid pressure in the injection interval, we found that the intersected fracture zone exhibits a period‐dependent hydraulic response close to radial flow perturbed by fracture‐related hydromechanical coupling effects. The main features of the interval’s hydraulic response were reproduced by an uncoupled diffusion solution for radial flow, which was used to derive apparent hydraulic properties. The largest deviations from this model occur for the phase shifts and correlate with the pressure amplitude. This non‐linear expression of hydromechanical coupling associated with deformable fractures was interpreted in terms of a pressure‐dependent effective compliance of the fractures that affects their effective storativity. The period dependence is likely related to the spatial heterogeneity expected in fractured rocks and the varying sensitivity of the hydraulic response for different periods. Accounting for these effects is necessary for a correct hydraulic characterization in fractured environments and is valuable for inferring fracture mechanical behaviour.

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“…In contrast to constant‐rate pumping tests, oscillatory hydraulic tests can be designed in a mass‐conservative manner such that there is no net water extraction or injection into tested fractures, thereby minimizing alterations to the ambient stress and flow fields along the fracture (Cardiff & Barrash, 2015; Rabinovich et al., 2015). In applications that require continuous pumping (e.g., geothermal production), a periodic pressure signal can be superimposed at the pumping well by systematically varying flow rates above and below a long‐term pumping rate, allowing reservoir characterization to occur without interrupting production operations and minimizing revenue losses (Fischer et al., 2018; Fokker et al., 2021; Salina Borello et al., 2019). Finally, because the frequency of the input signal is known, recorded observation signals are readily extracted from instrument noise, instrument drift, and/or hydrologic noise (e.g., evapotranspiration and recharge events) using standard linear signal processing techniques (Bakhos et al., 2014).…”

Section: Introductionmentioning

confidence: 99%

Stiff, Smooth, and Solid? Complex Fracture Hydraulics' Imprint on Oscillatory Hydraulic Testing

Patterson,

Cardiff

2023

Water Resources Research

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Fractured bedrock aquifers, especially deep aquifers, represent increasingly common targets for waste storage and alternative energy development, necessitating detailed quantitative descriptions of fracture hydraulic properties, geometry, and connectivity. Yet, multi‐scale characterization of the physical properties that govern fluid flow through and storage in fractured bedrock remains a fundamental hydrogeologic challenge. Oscillatory hydraulic testing, a novel hydraulic characterization technique, has been showing promise in field experiments to characterize the effective hydraulic properties of bedrock fractures. To date, these characterization efforts utilize simplified diffusive analytical models that conceptualize a non‐deforming, parallel‐plate fracture embedded within impermeable host rock, and have found that the returned fracture hydraulic parameter estimates exhibit an apparent period‐dependence. We conduct synthetic experiments using three different numerical models to examine proposed mechanisms that might contribute to the observed period‐dependence including heterogeneous flow and storage within the fracture (i.e., aperture heterogeneity), fracture‐host rock fluid exchange, and fracture hydromechanics. This work represents the first systematic analysis that seeks to understand the process(es) occurring within a bedrock fracture that might be contributing to this apparent period‐dependence. Our analysis demonstrates that all investigated mechanisms generate period‐dependent effective hydraulic parameter estimates, each with their own potentially diagnostic trends; however, fracture hydromechanics is the only explored mechanism that consistently reproduces period‐dependent trends in parameter estimates that are consistent with existing field investigations. These results highlight the need to develop more complex numerical modeling approaches that account for this hydromechanical behavior when characterizing fractured bedrock aquifers.

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Harmonic Pulse Testing for Well Monitoring: Application to a Fractured Geothermal Reservoir

Cited by 17 publications

References 50 publications

Aquifer Characterization and Uncertainty in Multi‐Frequency Oscillatory Flow Tests: Approach and Insights

Aquifer Characterization and Uncertainty in Multi‐Frequency Oscillatory Flow Tests: Approach and Insights

Period‐ and Pressure‐Dependent Hydraulic Properties of a Fractured Granite Inferred From Periodic Pumping Tests

Stiff, Smooth, and Solid? Complex Fracture Hydraulics' Imprint on Oscillatory Hydraulic Testing

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