SU693236A1 - Method of determining hydrogen content of liquid in a rock sample by nuclear magnetic resonance means - Google Patents

Description

(54) METHOD FOR DETERMINATION OF HYDROGEN CONTAINMENT

LIQUIDS IN THE SAMPLE OF MOUNTAIN BREED METHOD

Claims (2)

NMR This method is rapid and does not require pre-extraction of samples. However, the well-known method has significant drawbacks: it does not provide sufficient accuracy in determining the iodine content of the liquid in the sample. It does not allow the drainage of water to the extent of non-uniform samples and samples whose length exceeds the length of the sensor chamber. The object of the present invention is to improve the accuracy of determination; water hydrogenation in the pore space of rock samples by NMR by eliminating the effect of the inhomogeneity of the magnetic field on the measurement results, in particular, when determining the hydrogen content of the liquid in samples whose length exceeds the sensor chamber length, and also in non-uniform samples. The goal is achieved by moving the sample along the sensor chamber and measuring the amplitude of the NMR signal at consecutive positions of the sample in the chamber, then moving the reference along the sensor chamber and measuring the amplitude of the NMR signal at successive reference positions in the sensor chamber, and the content of hydrogen nuclei. it is determined on the basis of the ratio of the sample where the content of hydrogen nuclei in the sample; N. - content of hydrogen nucleus in the standard; F is the area bounded by the curve ° of the dependence of the amplitude of the signal on the position of the sample in the gauge measure; F is the area bounded by the dependence of the signal amplitude on the position of the reference in the sensor chamber. The proposed method of determining the water content of a liquid in samples of torus rocks by NMR will combine from the following sequence of operations: a) install the sample at the input sensor chamber so as to obtain a signal equal or close to zero b) move the sample along the axis of the chamber sensor, at 5-6 consecutive positions, measure the amplitude of the NMR-A signal (x); The measurement points are evenly distributed along the length of the chamber; the movement takes place until a zero signal is obtained at the output from the sensor chamber ;. c) construct the curve A (x) depending on the amplitude of the signal from the position of the sample in the chamber relative to its input end and calculate the area bounded by THIS curve pQgp; df) the operations indicated in art. 1–3 with a standard containing a fair number of protons and an additional value of the area of the amplitude curve for the standard; . g) determine the hydrogen content of the sample from formula (1). The formula was invented The method for determining the hydrogen content of a liquid in a sample of doped rock by NMR by sequentially placing the sensor of the sample under study and a standard containing a known amount of hydrogen nuclei and comparing the signals from them with that In order to improve the accuracy of determining the hydrogen nucleus hold, by eliminating the effect of the inhomogeneity of the magnetic field in the sensor chamber on the measurement results, the sample is moved along the sensor chamber and measuring the magnitude of the signal amplitude and successive positions of the sample in the chamber, then moving the standard along the sensor chamber and measuring the amplitudes of the NMR signal at successive positions of the reference in the sensor chamber, and the content of the nuclei of hydrogen is determined based on the ratio: H - and 1P6P sample-p7 where Novr content of hydrogen nucleus in the sample; N d - the content of hydrogen nucleus in the standard; F is the area bounded by the CID of the dependence of the signal amplitude on the position of the sample in the sensor chamber; 5 6932366. p is the area bounded by curve 1. Cobran and V.N., Leparska N.D. sig amplitude dependencies Determination of the physical properties of mountain Nala from the position of the standard, M, 1957. in the sensor chamber. Sources of information, 5 2.A.Timur, 3.pe-troB-Tec1inoeog. taken into account in the examination21. No. 6, 775, 1969 (prototype)