RU2209965C2 - Method of examination of deposits formed on walls of well flow string and device for method embodiment - Google Patents

Abstract

FIELD: well research; designed for determination of longitudinal profile and physico-chemical properties of heavy hydrocarbon and salt deposits on walls along flow string, and also for rock sampling from walls of uncased well. SUBSTANCE: method includes lowering on rope of multisectional sampling device into well flow string filled with fluid; sectional sampling of solid deposits from flow string walls in at least three points uniformly spaced over internal circumference of flow string. Operation of each section over well depth is accomplished alternately at corresponding values of fluid column hydrostatic pressure or by building up of required excessive pressure at wellhead. Then, taken samples are subjected to measurement of their thickness and physico-chemical analysis at surface. Device for method embodiment has rope suspension unit, body with radial cylinders accommodating sampling bushing capable of radial extension, and hydromechanical power mechanism for bushing extension. Device is provided with several successively connected autonomous sections, each of which has in body three radial cylinders located at angle of 120 deg.on same horizontal plane and accommodating sampling bushings in form of stepped sleeves with spherical stops, side bypassing longitudinal channels and toothed cut made on internal surface, two branch pipes connected to body from atop and from below whose cylindrical chambers accommodate hydromechanical power mechanism isolated from fluid medium by diaphragm rated for preset rupture pressure and installed in upper branch pipe, under its side holes hydraulically communicating diaphragm with well fluid. EFFECT: higher efficiency and simplification of process of examination of well flow string for quantitative and qualitative evaluation of formed solid deposits on its walls. 3 cl, 2 dwg

Description

 The invention relates to the field of well research and is intended to determine the longitudinal profile and physicochemical properties of heavy hydrocarbon and salt deposits on the walls along the production string, and can also be used for lateral sampling of rocks from the walls of an open hole.

 A known method for determining the presence of solid deposits on the walls along the production casing consists in the sequential descent into the well on the rope of patterns of various diameters. By their patency in the wellbore, changes in its cross section are determined, including the thickness of solid deposits on the walls to its maximum value [1].

 This method does not allow to determine the shape of the profile and the depth of the onset of solid deposits, as well as to take samples of deposits from the given depths of the well. In addition, when lowering the templates into the production casing, the actual thickness of the deposits is distorted due to cutting of their soft layer and it is necessary to carry out multiple tripping operations on the template.

 There is also a method of determining the transverse dimensions and the longitudinal profile of the wellbore using a profiler device, lowered into the well by cable. The device contains a housing, a displacement transducer, measuring levers made in the form of an elastic spring with a strain gauge concave to the axis of the profiler, one end of which is designed for contact with the well wall, and the other with a strain gauge glued on its surface [2].

 However, the profiler used for boreholes with an open bore of large diameter and in the study of a cased hole with a small amplitude of change in diameter gives measurement errors and does not carry out sampling of deposits to determine their physicomechanical properties and chemical composition. In addition, it is not applicable for determining the longitudinal profile of asphalt-resin-paraffin deposits (AFS) on the walls of the column due to the fact that the measuring levers cut into the deposits and their actual thickness is distorted.

 In technical essence, the closest to the proposed invention is a device for research and sampling of rocks, comprising a housing and an electric motor, a piston pump, cylinders with rock sampling sleeves in the form of hollow rods with pistons, a cylinder with a probe rod and a piston, a distribution element, communicated with the pressure and drain lines of the pump, intake and drain tank [3].

 This device has a complex structure and a large number of interconnected and interdependent nodes. It does not provide accuracy in determining the thickness of sediments along the perimeter of the column due to the longitudinal location of the rock sampling sleeves in the housing and sampling of sediments in one run from several predetermined depths of the well with large intervals between sampling points. In addition, the device is not intended for sampling sediment samples in a cased well and there is a high probability of damage to the column by a probe rod.

 The aim of the invention is to increase the efficiency and simplify the process of studying the production casing of a well for the quantitative and qualitative assessment of the formed solid deposits on its walls by ensuring both the accuracy of measuring the thickness of these deposits and the possibility of determining their physicochemical properties along the depth of the column.

This goal is achieved by the fact that in the production casing of a well filled with liquid, a multi-section sampling device is lowered on the rope, with the help of which at each given depth sectional sampling of solid deposits is carried out from the walls of the column at least at three points evenly located along its inner circumference . In this case, the operation of each section along the depth of the well is carried out alternately at the corresponding values of the hydrostatic pressure of the liquid column or the creation of the necessary overpressure at the wellhead. Then, a thickness measurement and a physicochemical analysis of the selected samples are performed on the surface. In terms of the device, the goal is achieved in that the sampling device consists of several series-connected autonomous sections. Each section is equipped in the housing with three radial cylinders located at an angle of 120 ^o on one horizontal plane, and placed therein with the possibility of radial movement of the sampling sleeves, made in the form of stepped sleeves with spherical stops, side bypass longitudinal channels and serrated notches made in the inner surface, two nozzles connected to the housing from the bottom and top, in the cylindrical chambers of which is placed a hydromechanical power mechanism isolated from idkostnoy environment diaphragm. The latter is designed for a given burst pressure and is installed in the upper nozzle under its side openings, hydraulically communicating the nozzle cavity above the diaphragm with the borehole fluid. In this case, the hydromechanical power mechanism consists of the upper and lower pistons located in the cylindrical chambers of the upper and lower nozzles and rigidly interconnected by a rod with a conical pusher interacting with the spherical stops of the stepped sleeves. The internal cavities of the chambers located above the upper piston and under the lower piston are hydraulically communicated by means of a capillary channel with a filter element on the upper piston passing through the axes of the pistons and rod. Moreover, the diameter of the upper piston is smaller than the lower, and the surface of the conical pusher has a thin coating layer.

 Figure 1 shows in longitudinal section one section of the proposed device during descent into the well; in Fig.2 - section A - A in Fig.1 - the position of the sampling sleeves at the time of sampling of sediments.

 The device consists of several series-connected autonomous sections. Each section contains a housing 1 with radial cylinders 2 with sampling sleeves arranged in them with the possibility of radial movement, made in the form of stepped sleeves 3 with spherical stops 4, side bypass longitudinal channels 5 and gear notches 6 made in the inner surface (see Fig. 2) connected to the housing 1 of the upper 7 and lower 8 nozzles, each of which respectively has a cylindrical chamber 9 and 10. The upper nozzle 7 under the side holes 11 is sequentially provided with a diaphragm 12, calculated This is set at a predetermined burst pressure and placed in the chamber 9 by the piston 13, and in the first section above the side openings 11, an additional rope suspension assembly 14. The lower cylindrical chamber 10 is also equipped with a piston 15 and a blind adapter 16 for connecting the next section. Pistons 13 and 15 are rigidly connected to each other by a rod 17 with a conical pusher 18 interacting with the spherical stops 4 of the sleeves 3. A thin coating layer is applied to the surface of the conical pusher 18 before the descent, for example, easily removable paint for marking on it in case of incomplete extension of the stepped sleeves 3 in the presence of superhard deposits (crystalline salts) on the walls of the column. The internal cavities of the cylindrical chambers 9 and 10 located above the piston 13 and below the piston 15 are hydraulically communicated by means of a capillary channel 19 with a filter element 20, for example, made in the form of a multilayer metal mesh, while the space in the housing 1 between the pistons 13 and 15 has Permanent air chamber 21.

 The device is manufactured in several diametrical versions of the casing and conical pusher with the corresponding radial extensions of the sampling sleeves in the casing for various internal diameters of the well columns.

 The method is as follows.

 After filling the well with a kill fluid, tubing is removed and refilled with the same fluid to the wellhead. Depending on the number of specified exploration depths of the production casing for constructing a longitudinal profile of solid deposits and studying their physicochemical properties at the same depths, the required number of sections of the sampling device is collected. To do this, when assembling in series, starting from the first section, diaphragms 12 are installed in them according to increasing values of their burst pressure, corresponding to the hydrostatic pressure of the liquid column at given depths of the column research.

 The assembled sampling device on the rope descends into the column 22 with solid deposits 23 on its walls (see figure 1). During the descent of the device under the diaphragm 12, the hydromechanical power mechanisms remain isolated from the borehole fluid and are in the air, and the sampling step sleeves 3 due to the action of the fluid pressure on their outer end surfaces remain in the housing 1. Upon reaching the interval of the first specified depth of study of the column from hydrostatic pressure of a liquid column transmitted through the side holes 11 of the pipe 6, the diaphragm 12 of the first section ruptures. The fluid pressure instantly acts on the piston 13 and moves it down to the stop of the housing 1. The piston 15 in the chamber 10, rigidly connected through the rod 17 with a conical pusher 18 and the upper piston 13, also moves down. The volume of the cylindrical chamber 10 is selected so that the air pressure with a small stroke of the piston 15 is almost not increased (according to the law of the isothermal process of air compression). When the piston 13 reaches the limiter in the housing 1, the conical pusher 18 of the rod 17 extends the stepped sleeves 3 as much as possible and the latter are inserted with sharp edges into the deposits 23 of the column 22, and the liquid from the inner cavity of the sleeves 3 is displaced through the side longitudinal channels 5 by sample samples. At the time of sampling deposits, the device stops and due to the proportional extension and uniform distribution of the stepped sleeves 3 around the circumference, it is centered along the axis of the column, and at the wellhead the depth of sampling is fixed sample deposits. The borehole fluid through the filter 20 and the capillary channel 19 enters under the piston 15 into the chamber 10 and the fluid pressure above the piston 13 and under the piston 15 is aligned with the time delay. Since the area of the piston 15 is larger than the area of the piston 13, at equal liquid pressures, the force acting from below on the piston 15 is greater and it moves up with the rod 17 and its conical pusher 18. The stepped sleeves 3 released from the support with spherical stops 4 and with selected samples in the internal cavity due to the fluid pressure acting on their stepped end surfaces, return to their original position. Further, the device, due to its own weight, continues to descend the column to the next specified depth. When the next predetermined depth is reached, the corresponding sections of the device are activated similarly to the above. After sampling sediment at all specified column depths, the device is raised to the surface. From the outside of the housing 1, the sampling sleeves 3 are easily removed and after draining the water contained in them, the length of the selected sediment samples in their inner cavity through the lateral longitudinal channels 5 is determined, and their physicochemical properties are studied from the samples.

The length of the sediment samples obtained with the full extension of the sampling sleeves 3 in the well corresponds to the thickness of the deposits on the walls of the column. Incomplete extensions of the sampling sleeves 3 are determined by the traces left by their spherical stops 4 on the surface of the conical pusher 18 with a special coating. In this case, the actual thickness of the deposits on the walls of the column is determined by the formula:
δ _from = l _vol + (R _to -r + L),
where δ _from is the thickness of the deposits on the walls of the column;
l _about - the length of the selected samples in the cavity of the sleeves;
R _to - the inner radius of the column without deposits;
r is the radius of the conical pusher on the maximum plane of the point of contact of the spherical stop of the sleeves with a conical pusher (determined by the traces left);
L is the length of the sampling sleeves with a spherical focus.

 The creation of excess pressure for the implementation of the method is mainly required when examining the column with predetermined depths close to the wellhead. In this case, the magnitude of the acting radial forces of extension of the sampling sleeves created by the hydrostatic column of liquid becomes insufficient for the introduction of sleeves into superdense salt deposits on the walls of the column. For this, the wellhead is sealed and after stopping the sampling device at predetermined depths, the necessary overpressure is created at the wellhead to break the diaphragm of the corresponding sections of the device.

 The technology is easily implemented in the process of underground or overhaul of wells.

 A new set of claimed essential features allows for one descent of the deep device into the well to simultaneously quantify and qualitatively evaluate the formed solid deposits on the surface of the walls of a cased well to select the most effective method for cleaning its casing based on knowledge of the properties of deposits, such as mechanical strength and chemical composition .

 The technical solution also allows for one descent of the sampling device to carry out lateral sampling of rocks from the walls of an open hole with long sampling intervals along the depth of the well.

Sources of information
1. P.N. Lavrushko. Underground well repair. - M .: Nedra, 1969, p. 272.

 2. A.S. 1382937, cl. E 21 B 47/08, 03/23/86.

 3. A.S. 1268718, cl. E 21 B 49/06, 11/7/86.

Claims (3)

 1. A method for studying deposits formed on the walls of a production casing of a well, comprising filling a well without tubing with a kill fluid and lowering a measuring device into it, determining a longitudinal profile and composition of solid deposits along the depth of the casing, characterized in that at each given depth with using a multisectional sampling device, sectional sampling of solid deposits from the walls of the column is carried out at at least three points uniformly located on the inside It its circumference, wherein the operation of each section of borehole depth produced alternately at the corresponding values of the hydrostatic fluid column pressure or the creation of the required excess pressure at the wellhead, and then to produce thickness measurement surface and physico-chemical analysis of samples. 2. A device for the study of deposits on the walls of the production casing of the well, containing a node of a cable suspension, a housing with radial cylinders and radial displacements of sampling sleeves, a hydromechanical power mechanism for extending the sleeves, characterized in that it consists of several series-connected autonomous sections, each of which is equipped in the housing with three radial cylinders located at an angle of 120 ^o on one horizontal plane, and the size taped sampling sleeves in them, made in the form of stepped sleeves with spherical stops, lateral bypass longitudinal channels and serrated notches made in the inner surface, two nozzles connected to the housing from below and above, in the cylindrical chambers of which there is a hydromechanical power mechanism isolated from liquid medium with a diaphragm designed for a given burst pressure and installed in the upper nozzle under its side openings hydraulically communicating the diaphragm of wellbore fluid.  3. The device according to claim 2, characterized in that the hydromechanical power mechanism comprises upper and lower pistons located in the cylindrical chambers of the pipes, rigidly interconnected by a rod with a conical pusher interacting with spherical stops of the stepped sleeves, and the internal cavities of the cylindrical chambers located above the upper piston and under the lower piston, hydraulically communicated using a capillary channel passing through the axis of the pistons and rod, with a filter element on the upper piston, while the diameter p of the upper piston is smaller than the diameter of the lower, and the surface of the conical pusher has a thin coating layer.

Images