SU1409894A1 - Apparatus for determining filtration properties of rocks - Google Patents

Abstract

The invention relates to a technique for studying the physical properties of porous bodies, namely to the study of the filtration properties of rocks under conditions of elevated pressures, and can be used in hydrogeology, mining and oil and gas industry. The purpose of the invention is to improve the accuracy of determining the filtration properties of rocks. The camera body, into which the insert assembly with the core holder is screwed, has in its sides: in the second part, two channels, one of which is intended for supplying a crimping liquid. The second side channel with a shut-off valve of variable diameter is made horizontally in the side wall of the casing of the high pressure chamber. An overhead power cylinder with an inner belt diameter was used, which makes it possible to accommodate a plunger of variable diameter in proportion to it. At the same time, a channel with a fitting for creating an axial compression of the sample for connection to the hydrojump circuit is located horizontally in the side wall of the hollow power cylinder. The use of a variable-diameter plunger allows the linear displacement indicator to be coaxially connected to it through an axial bore in the lower part of the hollow power cylinder. The use of a second channel with a variable-diameter shut-off valve for venting gas from the internal cavity of the high-pressure chamber and the linear displacement indicator increases the accuracy of determining the filtration properties of rocks. .1 il. W SL 4 about CD 00 CD 4ib

Description

The invention relates to devices for studying the physical properties of porous materials, namely, is -. following the filter properties of rocks under conditions of increased pressure, and can be used in hydrogeology, mining and oil and gas industry.

The aim of the invention is to increase the accuracy of determining the filtration properties of rocks,

The drawing shows the mutual arrangement of the elements of the device for determining the filtration properties of 5 rock pores, the operating mode.

The COCTOPJT device from the camera body 1 in the form of a hollow metal cylinder 5 is screwed into the internal cavity of the metal insert 220 assembled with the core holder 3, in which a rock sample 5 is enclosed in the elastic cuff 4. To seal the insert 2, sealing rings made of bronze 25j fluoroplastic 7 and stainless steel 8 are used. Insert 2 is filled with inlet 9 and outlet 10 fluid channels in which fittings 11, 12 are installed, Core holder 3 cre-30 is fed to the insert 2, for example, by means of bolts, -B ,, the side part of the housing 1 has a channel 13 for supplying a crimping liquid into the internal working cavity 14 of the chamber 1 and the channel 15 for ot-, j3, 9ft ,. gas from the internal cavity 14 ka, p, b1-, 1 as it is filled with a crimping liquid. Channels 13 and 15 are made with threads in the outer part. A fitting 16 is installed in channel 13, and a stop valve 17 is installed in Q, 15. A hollow power cylinder 18 with an internal variable diameter assembled with a variable-diameter plunger 19 is screwed into the lower part of housing 1, made 45 in proportion to the inner diameter of the hollow power cylinder 18. For tightness of the hollow power cylinder 18 in the housing of the chamber 1 are installed o-rings 20, In the side wall of the hollow power cylinder 18 there is a horizontal channel 21 threaded in the outer part, in which the set-up fitting 22 for connection to a hydrojump system that generates axial pressure on the plunger 19. Coaxially with plunger 19 to the power cylinder 18 with the help of a holder consisting of a holder case 23, a coupling 24, they came

50

55

g

five

0 5 0, Q 5 0

five

screw 25, fixed stationary part 26 of the indicator 27 linear displacement. The movable part of the indicator 28 of linear displacement relates to the lower end of the plunger 19. O-rings 29 are used to seal the holder 23. The device is mounted on the frame 30.

The device works as follows.

When the device is connected to a hydrojump system to create axial (PO,.) And lateral (PSOK) pressures that can be unequal among themselves, separate pressure sources are used, for example, in the form of a compressor of a hydraulic press, a pump, etc. Through channel 13 with nipple 16 and channel 21 with nipple 22, uniformly proportional pressures P and are created, and through nipples 11 and 12 with inlet 9 and outlet 10, fluid channels are made through the filter working agent through the rock sample 5.

The stresses generated on the rock sample Pp; - and Pgpn cause a strain; and 1O of the sample under study.

When the device is connected to a hydro-pressing system to create an axial pressure-lighter Pg, a working agent is fed into the internal cavity of the metal hollow power cylinder 18 through fitting 22 and channel 21. The hollow power cylinder 18 is made with an internal variable diameter, which allows, commensurately, to place in it a plunger 19 of variable diameter, executed in steps with a large diameter in the upper part and a smaller diameter in the lower part. The lower part of the smaller diameter plunger 19 allows, through the axial bore with the thread in the outer part and the holder 23 installed in it in the lower part of the hollow power cylinder 18 COOSNO, to connect the movable part 28 of the linear displacement indicator 27, which serves to measure the axial linear deformations studied Sample 5. To seal the hollow power cylinder 18, sealing rings are installed in the body of chamber 1.

The metal holder consisting of the holder body 23, the sleeve 24 and the clamping screw 25 securely holds the fixed part 26 of the linear movement indicator so that the movable part 28 of the linear movement indicator 27 touches the end of the lower part of the plunger 19 of variable diameter. To seal the holder 23 in the housing of the hollow power cylinder 18, sealing rings 29 are used.

The working agent under pressure falls under the top of the plunger 19

larger diameter and pushes it upward, 1o about the internal cavity 14 of the camera -1

15

clamping the sample 5 to the fixed insert 2. Under the action of the voltage Ppg, the sample experiences linear axial deformation l1, which is indicated by the movement of the plunger 19. The moving part 28 of the indicator 27 follows the movement of the plunger 19, and the deflection of the arrow on the indicator 27 shows the value of the linear deformations l1 which is used to calculate the permeability coefficient. (Kj, -) of the rock sample 5. The location of the channel 21 in the side wall of the hollow power cylinder 18 makes it possible to place in the axial hole 25 of the lower part of the hollow power cylinder 18 the holder 23 assembled with the indicator 27 linear displacements arranged coaxially with the variable plunger diameter 19, which improves the measurement accuracy of the axial linear deformations, and hence the permeability coefficient, improves the tightness and reliability of the device, since by using the linear displacement indicator it is possible to establish the transition from elastic deformation to plastic and brittle, depending on the type and structure of the rocks.

When creating lateral pressure

high pressure, the displaced air through the channel 15, the gap between the walls of the socket and the gate valve 17 and the G-shaped channel inside the gate valve 17 comes out. The appearance of a crimping fluid in the outer channel 15 indicates that the inner cavity 14 of the high-pressure chamber 1 is completely filled and there is no gas bubble, after which the stop valve 1 is screwed in as far as it will go, tightly closing the outlet from the inner cavity 14 of the high-pressure chamber 1. This allows you to create a uniform lateral

compression P,

SIDE

sample, which increases the point

thirty

35

The determination of the transverse radial deformation of the sample is lg.

The transverse radial deformation dg of the sample is directly proportional to the change in the volume of the AV sample under the effect of side compression on the side. Moreover, the sample iV is equal to the amount of compressing fluid fixed on the scale of the hydraulic press entered into the internal cavity 14 of the high pressure chamber 1

sample 5 from the initial Pg value to the specified value. Completion of the deformation is established by stopping the movement of the arrow indicator 27 of linear displacements.

Pg. compressing the sample through the nozzle 16 onto the sample, then the channel 13 enters the internal cavity 14 of the metal hollow single-layer high-pressure chamber 1. The pressure of the crimping fluid is transmitted through the core holder 3 to the elastic cuff 4 and then to the side surface of the rock sample 5.

Moreover, a gas bubble, formed as the compressing fluid fills the inner cavity 14 of the high-pressure chamber 1, is withdrawn. I go through the channel 15 with a shut-off valve 17 located horizontally in the body of the high-pressure chamber 1 at the level of a clamping metal insert 2 with the internal cavity 14 of the high-pressure chamber 1. In this case, the shut-off valve 17 is used as a device for passing or closing the flow of liquid or gas. If the stop valve is not screwed in as far as it will go, the outlet from the channel 15 is open to the outside.

As lifting crimping fluid

high pressure, the displaced air through the channel 15, the gap between the walls of the socket and the gate valve 17 and the G-shaped channel inside the gate valve 17 comes out. The appearance of a crimping fluid in the outer channel 15 indicates that the inner cavity 14 of the high-pressure chamber 1 is completely filled and there is no gas bubble, after which the shut-off valve 17 is screwed up to the stop, tightly closing the outlet from the inner cavity 14 of the high-pressure chamber 1. This allows you to create a uniform lateral

compression P,

SIDE

sample, which increases the point

The determination of the transverse radial deformation of the sample is lg.

The transverse radial deformation dg of the sample is directly proportional to the change in the volume of the AV sample under the effect of side compression on the side. Moreover, the sample iV is equal to the amount of compressing fluid fixed on the scale of the hydraulic press entered into the internal cavity 14 of the high pressure chamber 1

sample 5 from the initial Pg value to the specified value. Completion of the deformation is established by stopping the movement of the arrow indicator 27 linear displacements.

The obtained values of dg and l 1 are used to determine the coefficient of permeability K, p, which is due to the presence of deformation of the sample under study.

Through fittings 11 and 12 and channels 9 and 10 in the metal insert 2, which is screwed into the internal cavity of the high pressure chamber 1, the device is connected to the hydraulic circuit of the installation, i.e. the working agent is filtered through the rock sample under study. The insert is attached to the core holder 3 with sample 5 of the rock in the elastic cuff 4, for example, with the aid of bolts. To create a sealed, insert 2 seals are used.

Body rings made of bronze 6 and stainless steel 8.

The filtering agent is under pressure through fitting 11, supplying fluid channel 9, core holder 3 is evenly distributed over the entire surface of the end face of the rock sample 5. Then a pressure differential is created and the working agent is filtered through the test rock sample. The working agent filtered through the sample through the discharging fluid channel 10 with the fitting 12 enters the measuring device, for example the flow meter.

Filtration through the sample can be carried out both in stationary (with a constant pressure drop) and in non-stationary (with a variable pressure drop) filtration modes.

The amount of working agent filtered through the sample, as well as the pressure drop, is used to determine the coefficient of perceptibility of the rock under study under the conditions of the action of hydro-pressing.

 RON

The proposed device allows

predict the filtration properties of rocks at depths that have not yet been reached by drilling, which increases the geological information content and, therefore, makes it possible to reduce the volume of deep drilling.

Claims (1)

Invention Formula A device for determining the filtration properties of rocks, comprising a high-pressure chamber housing mounted on a frame in the form of a hollow metal cylinder with a KOBiaHM channel and fitting, a metal insert with two channels with fittings, a core holder with a sample with 0 five 0 0 five rocks in the elastic cuff, plunger, hollow power cylinder with bore and fitting, sealing rings, characterized in that, in order to improve the accuracy of determining the filtration properties of rocks, it is additionally equipped with a linear displacement indicator with a holder executed in the form of a holder body, a coupling and a clamping screw, a second side channel is additionally inserted, located horizontally in the chamber of high pressure at the level of the junction of the metal insert with the internal cavity of the high pressure chamber, and beyond A variable-diameter porous valve located on the outer side of the side wall of the high-pressure gum body, the outer surface of which ends with a head from the larger-diameter crowns and a dull smooth convex surface on the smaller diameter side, the inner surface forms an L-shaped channel consisting of two mutually perpendicular channels: non-through axial, located in part of a larger diameter stop valve, and side valve, located in a part of a smaller diameter stop valve, The shut-off valve is installed in a threaded socket, the diameter of which is equal to the larger diameter of the shut-off valve and communicating with the second side channel; the plunger is made in steps with a larger diameter in the upper part and a smaller diameter in the lower part; the hollow power cylinder is made with an internal variable diameter proportionally with a variable diameter of the plunger and connected to the lower part of the body of the high-pressure chamber; the channel with the fitting is located horizontally in the side wall of the hollow power cylinder under the upper part of the plunger TERM diameter, coaxially connected to the linear displacement indicator. / 7  j D 22 27