SU1696944A1 - Method for determining crack resistance of friable materials - Google Patents

Description

one

(21) 4721014/28

(22) 07/14/89

(46) 12.7.91. Bul. №45

(71) Institute of Mining, Siberian Branch, USSR Academy of Sciences

(72) G.F.Bobrov, V.M. Zhigalkin and V.M. Sboev (53) 620.172.24 (088.8)

(56) Swenson S.V. The effect of the inertia of the testing machine is the truth of the values of the fracture toughness. - In book: Viscosity of high-strength materials destruction. M .: Metallurgists: -, 1973, p. 47-55.

(54) METHOD FOR DETERMINING THE CROSS-RESISTANCE OF A BRITELY MATERIAL.

(57) The invention relates to a test technique and can be used to determine the crack resistance of a brittle material. The invention is an increase in the accuracy and reliability of testing rock core samples. Core samples 1 of a rock of length L are used. In core 1, directly after sampling, an incision 2 is made from the rock and the - field i with untreated (non-anni) highlanders with hard end references 3 and 4 is placed. 3 m 4 mandrels are removed from the ratio C (2 .... 3) 8, where B is the notch width 2. In the notch zone 2 a microseismic signal is placed

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The expander 5. The loading is carried out, for example, by bending on the supports 6 and 7 with the force P until the specimens are destroyed in the hard loading mode. When loading, a load force — displacement of the notch banks is recorded. On one sample, the level U of the microseismic impulse emitted by a crack formed from an incision under load P is determined. For direct testing, the invention relates to a testing technique and can be used to determine the fracture toughness of a brittle material.

The purpose of the invention is to improve the accuracy and reliability of testing samples of rock cores.

The drawing shows a test specimen placed in end mandrels.

The method is carried out as follows.

Core samples 1 of the rock are used in length .. In core 1, immediately after the selection and the rock, an incision 2 is made and then the core is placed on rigid end mandrels 3 and 4. The distance C between picks 3 and 4 is chosen from the ratio

C (2 .... 3) -B, where B is the notch width 2.

In the area of the notch 2 place the mica-filter 6.

The loading is carried out, for example. by bending on supports 6 and 7 by force P until the specimens are destroyed in the regime of rigid loading. When loading register chart load force - movement of the notch.

On one sample, the level U of a microseismic pulse emitted by a crack resulting from a notch at the maximum load P is determined.

In the case of direct testing of specimens after reaching the ultimate load P, the overload loading alternates with repeated unloading. Unloading is carried out by exceeding the level U at the leading edge.

after reaching P, alternate loading on repeated unloading alternates. With each successive unloading, after the front level of the microseis impulse is exceeded, the foremost loading is continued while the microseismic impulse decreases below this level. The work of destruction is determined by the diagram, and the rock resistance to fracture is judged from it. 1 il.

microseismic pulses, and continue transboundary loading with a decrease in microseismic pulses below this level. According to the diagram, the loading force — the movement of the notch banks determine the work of destruction, and the fracture-resistance of the rock is judged from it.

Claims (1)

The invention The method for determining the crack resistance of a brittle material, according to which notched material samples are loaded under hard loading mode, is measured by the diegram loading force — the movement of the notch banks, after reaching limit loads alternate the ultimate loading with repeated unloading until the complete destruction of the sample, determine the type of destruction and determine the crack resistance of the material, and distinguish it from the fact that, in order to improve the accuracy and reliability of core rock samples After the selection of the breed, it is stirred in rigid end mandrels, The distance C between the mandrels is selected from the relation C (2 .... 3) B, where B is the notch width, is placed in the notch zone of a microseismic transducer, and the level of the microseismic pulse emitted by the notch under the maximum load is determined on one sample , with direct testing at each alternation, unloading is carried out after exceeding the specified level at the leading edge of the microseismic pulses, and the ultimate loading continues with decreasing microseismic pulses below the specified level.