The Scratch Test: An Attractive Technique for Determining Strength and Elastic Properties of Sedimentary Rocks

Schei, G.; Fjær, Erling; Detournay, Emmanuel; Kenter, C.J.; Fuh, Giin-Fa; Zausa, F.

doi:10.2118/63255-ms

Cited by 65 publications

(34 citation statements)

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“…Rock stiffness may vary a lot from one location to another, on all length scales. Even within the few centimetres covered by a core plug from a uniform formation, there may be large variations in stiffness (Schei et al 2000). Within 100 m range corresponding to the wavelength of a seismic wave, even larger variations will normally occur due to the presence of different rock types.…”

Section: H E T E R O G E N E I T I E Smentioning

confidence: 99%

Relations between static and dynamic moduli of sedimentary rocks

Fjær

2018

Geophysical Prospecting

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Static moduli of rocks are usually different from the corresponding dynamic moduli. The ratio between them is generally complex and depends on several conditions, including stress state and stress history. Different drainage conditions, dispersion (often associated with pore fluid effects), heterogeneities and strain amplitude, are all potential reasons for this discrepancy. Moreover, comparison of static and dynamic moduli is often hampered and maybe mistaken due to insufficient characterization of anisotropy. This paper gives a review of the various mechanisms causing differences between static and dynamic moduli. By careful arrangements of test conditions, it is possible to isolate the mechanisms so that they can be studied separately. Non‐elastic deformation induced by the large static strain amplitudes is particularly challenging, however a linear relationship between non‐elastic compliance and stress makes it possible to eliminate also this effect by extrapolation to zero strain amplitude. To a large extent, each mechanism can be expressed mathematically with reasonable precision, thus quantitative relations between the moduli can be established. This provides useful tools for analyses and prediction of rock behaviour. For instance, such relations may be used to predict static stiffness and even strength based on dynamic measurements. This is particularly useful in field situations where only dynamic data are available. Further, by utilizing the possibility for extrapolation of static measurements to zero strain amplitude, dispersion in the range from seismic to ultrasonic frequencies may be studied by a combination of static and dynamic measurements.

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Section: H E T E R O G E N E I T I E Smentioning

confidence: 99%

Relations between static and dynamic moduli of sedimentary rocks

Fjær

2018

Geophysical Prospecting

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“…The word intrinsic emphasizes that this energy is strictly used to cut the rock. A strong correlation between intrinsic specific energy and uniaxial compressive strength for various rocks is well established [48,49].…”

Section: Scratch Test Analysismentioning

confidence: 96%

“…The principle of the scratch test is to control and monitor the continuous shearing action induced by the motion of a 3 Geofluids diamond (PDC) cutting tool on the surface of a rock core sample [47,48]. The continuous high-resolution profile of rock strength (UCS) along the core sample is derived from the force acting on the cutter.…”

Section: Scratch Test Analysismentioning

confidence: 99%

An Experimental Study to Reduce the Fracture Pressure of High Strength Rocks Using a Novel Thermochemical Fracturing Approach

et al. 2019

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Current oil prices and global financial situations underline the need for the best engineering practices to recover remaining oil from unconventional hydrocarbon reservoirs. These hydrocarbon reservoirs are mostly situated in deep and overpressured formations, with high rock strength and integrity. Breakdown pressure of the rock is a function of their tensile strength and in situ stresses acting on them. Fracturing stimulation techniques become challenging when treating these types of rocks, and many cases approached to the operational limits. This leaves a small operational window to initiate and place hydraulic fractures. In this study, a new methodology to reduce the breakdown pressure of the high stressed rock is presented. The new method enables the fracturing of high stressed rocks more economically and efficiently. Fracturing experiments were carried out on different blocks, and the breakdown pressure was measured by creating a simulated borehole at the center of the block. Thermochemical fluids were injected to create the microfractures. These microfractures improved the permeability and porosity and reduced the elastic strength of the subjected samples prior to the main hydraulic fracturing job. The posttreatment experimental analysis confirmed the presence of microfractures which were originated due to the pressure pulse generated from the thermochemical reaction. The results of this study showed that the newly formulated method of thermochemical fracturing reduced the breakdown pressure by 38% in slim borehole blocks and 60% in large borehole blocks. Results also showed that the breakdown time to initiate the fractures was reduced to 19% in slim borehole blocks and 17% in large borehole blocks. The reduction in breakdown pressure and breakdown time happened due to the creation of microfractures by the pressure rise phenomenon in a new thermochemical fracturing approach.

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“…Richard et al (1998) further demonstrated that the friction coefficient of a scratch test is equal to the intrinsic friction coefficient of the tested rock. Schei et al (2000) analyzed the force acting on a scratch cutter and found that there is a strong correlation between the hardness of rock and scratch measurements. Based on this finding, Schei et al presented a preliminary model for rock hardness evaluation using scratch test results; however, the accuracy of the evaluation model is not very satisfactory.…”

Section: Introductionmentioning

confidence: 99%

A new approach to evaluate rock drillability of polycrystalline diamond compact bits using scratch test data

Han

Feng

2020

Energy Exploration & Exploitation

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Rock drillability is a comprehensive index that indicates the ease of drilling a hole in the rock mass, which is a main basis for the design of drilling bits, the optimization of drilling operational parameters, and the prediction of rate of penetration. This paper established a conversion relationship between mechanical specific energy measured from micro-drilling tests and mechanical specific energy measured from scratch tests, based on the consistency of rock breaking mechanism between these two types of tests. By incorporating the methodology of calculating rock drillability grade of polycrystalline diamond compact bits, a new mathematical model for predicting rock drillability of polycrystalline diamond compact bits is developed. Subsequently, a new method for acquiring continuous rock drillability profile by scratching the core surface is developed. A wide range of rocks with different hardness were tested by the proposed scratch method. The results show that the new model has high consistency with the results of laboratory micro-drilling tests. For example, the average errors of sandstone, shale, and carbonate test results are only 7.41%, 8.18%, and 4%, respectively. The new method can fully characterize the effect of mineral composition, cementation strength, and microstructure of rock on drillability. Besides, the new model has high utilization efficiency of expensive core samples because the core usually remains nondestructive after scratch tests.

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The Scratch Test: An Attractive Technique for Determining Strength and Elastic Properties of Sedimentary Rocks

Cited by 65 publications

References 0 publications

Relations between static and dynamic moduli of sedimentary rocks

Relations between static and dynamic moduli of sedimentary rocks

An Experimental Study to Reduce the Fracture Pressure of High Strength Rocks Using a Novel Thermochemical Fracturing Approach

A new approach to evaluate rock drillability of polycrystalline diamond compact bits using scratch test data

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