RU2158366C2 - Device for well research - Google Patents

Abstract

FIELD: oil wells operation, particularly, conduction of continuous recording of flow metering without use of compressed air for well stimulation. SUBSTANCE: device has flowmeter lowered into well on cable and fluid displacer attached to cable above flowmeter. Displacer is made in form of stringed on cable interconnected cylindrical members whose total length L is expressed by formula given in the invention description. Displacer is attached to cable at distance R from flowmeter expressed by equation given in the invention description. Cross-section area S of displacer member is constant over their entire length and is selected depending on preset flow rate and speed of recording of flow metering by formula S=q/V, where q is preset flow rate over wellbore, cu.m/h; V is speed of continuous recording of flow metering, m/h. EFFECT: higher efficiency. 1 dwg

Description

 The present invention relates to the operation of oil wells, namely to research production wells.

 A device for a borehole flow meter or flow meter is known (A. Petrov, “Methods and Measurement Technique in Field Well Research”, M., Nedra, 1972). The downhole flow meter contains a flow sensor in the form of a turbine, which is placed in the stream. The speed of rotation of the turbine is proportional to the intensity of the flow or fluid flow in the wellbore. The flow meter is lowered into the well on a wireline through tubing. The cable is sealed at the wellhead using a lubricator gland. Excite the well by pumping compressed air into the annulus. Moving the flow meter along the filter portion of the well, measure the intensity of the inflow or absorption of the well. The downhole flow meter allows you to determine the actual inflow or absorption of fluid by the reservoir or part of it and evaluate how well the well works. The disadvantage of a downhole flowmeter is the need to stimulate the well with a compressor, which significantly increases the cost of research and increases the risk of work (injecting compressed air into the well is dangerous due to the possibility of an explosion of a mixture of atmospheric air and gas released from oil).

 The well-known "Device for researching wells", see RF patent 2108458, Bulletin of inventions N 10 for 1998, which allows to conduct research wells with a flowmeter without excitation by their compressor, which we take as a prototype. The known device comprises a flow meter lowered into the well on a logging cable and is additionally equipped with a column of pressurized pipes with an inlet with a cap at the upper end and a drain hole with a check valve at the lower end and a cable clamp through which it is mounted on the logging cable above the flowmeter.

 When measuring the flow rate (determining the profile of the return), the device is lowered into the well. When the column approaches the liquid level, the lowering speed is reduced and, immersing the column at a low speed in the liquid, they achieve that the level is close to the original and the inlet is slightly higher (1-2 m) the liquid level in the well. At this moment, no liquid enters the internal cavity of the column, since the drain hole is blocked by a check valve, and the inlet is above the level. After that, the device is lowered into the well before the flowmeter is installed at the measurement point and after a certain period of time (from 30 seconds to 10 minutes) after the column is submerged under the liquid level, the meter reads. When the column is submerged under the liquid level, its internal cavity is filled through the inlet. As a result, the fluid level in the well decreases, the pressure of the fluid column on the formation decreases, and the flow of fluid from the formation begins. The presence and intensity of the inflow is recorded using a flow meter. At the end of measurements at a point, the device is raised so that the column rises above the liquid level. In this case, the check valve of the drain hole opens and the fluid from the inner cavity of the column is discharged into the wellbore. After restoration of the level in the well, the device is again lowered to installation at the next measurement point. Thus, the known device allows you to determine the profile of the inflow of the well without excitation by the compressor, pump and other types of equipment for the operation of wells.

 A disadvantage of the known device is the inability to conduct continuous registration of flow meter, which reduces the reliability and performance of the measurements.

The objective of the invention is to provide a device that allows for continuous registration of flow meter. The problem is solved in that the displacer is made in the form of a string stringed onto a logging cable and connected to each other by cylindrical elements with a total length L of:
L (h _p - h _k ) + (l _ds + l _dp ) + (h _d - h _st ),
where h _p - the depth of the sole of the reservoir, m;
h _to - the depth of the roof of the reservoir, m;
l _ds - the length of the additional flat cable, m;
l _DP - the length of the additionally raised cable, m;
h _d - the depth of the dynamic liquid level, m;
h _article - the depth of the static liquid level, m

The displacer is mounted on the cable so that its upper end is spaced from the flow meter at a distance R equal to:
R = h _p - h _st + l _ds .

The cross-sectional area S of the displacer elements is constant over their entire length and is selected depending on the given flow rate and the rate of registration of the flowogram according to the formula:
S = q / V,
where q is the specified flow rate of the fluid along the wellbore, m ³ / h;
V is the speed of continuous recording flow meter, m / h

Comparative analysis revealed the following significant differences of the proposed device from the prototype:
- the displacer is made in the form of a column of stringable and interconnected cylindrical elements with a total length L, component:
L = (h _p - h _k ) + (l _ds + l _dp ) + (h _d - h _st ),
where h _p - the depth of the sole of the reservoir, m;
h _to - the depth of the roof of the reservoir, m;
l _ds - the length of the additional flat cable, m;
l _DP - the length of the additionally raised cable, m;
h _d - the depth of the dynamic liquid level, m;
h _article - the depth of the static liquid level, m;
- the displacer is mounted on the cable so that its upper end is spaced from the flow meter at a distance R equal to:
R = h _p - h _st + l _ds ;
- the cross-sectional area S of the displacer elements is constant over their entire length and is selected depending on a given flow rate and flowmeter recording speed according to the formula:
S = q / V,
where q is the specified flow rate of the fluid along the wellbore, m ³ / h;
V is the speed of continuous recording flow meter, m / h

Due to the fact that the displacer is made in the form of a string stringed onto a logging cable and connected to each other by cylindrical elements with a total length L of:
L = (h _p - h _k ) + (l _ds + l _dp ) + (h _d - h _st ),
where h _p - the depth of the sole of the reservoir, m;
h _to - the depth of the roof of the reservoir, m;
l _ds - the length of the additional flat cable, m;
l _DP - the length of the additionally raised cable, m;
h _d - the depth of the dynamic liquid level, m;
h _article - the depth of the static liquid level, m,
when registering a flow chart, the displacer is raised from the liquid level. At the same time, the fluid level in the well decreases, fluid flows from the reservoir and fluid flow is provided throughout the wellbore at the same time that the flow meter approaches the reservoir, runs along the filter portion of the reservoir and extends beyond the reservoir. Fixing the displacer on the cable is such that its upper end is spaced from the flow meter at a distance R equal to:
R = h _p + h _st + l _ds ,
what provides a predetermined location of the displacer and maintaining the flow rate during registration of the flow chart. Due to the fact that the cross-sectional area S of the displacer elements is constant along their entire length and is selected depending on a given flow rate and flowmeter recording speed according to the formula:
S = q / V,
where q is the specified flow rate of the fluid along the wellbore, m ³ / h;
V is the speed of continuous recording flow meter, m / h;
it is ensured that any flow rate is kept constant at any flowrate registration speed.

 Based on the foregoing, we can conclude that the proposed device meets the criteria of the invention of "Novelty." The applicant is not aware of technical solutions containing similar features that distinguish the claimed invention from the prototype, which allows us to conclude that it meets the criterion of "Inventive step".

 The proposed device is shown in the drawing.

The device comprises a production well 1, into which a flowmeter 4 is lowered to the logging cable 3 downstream of the reservoir 2 by the length of an additional deflated (bypassed) cable l _{ds. A} displacer 5 is fixed above the flowmeter 4 on the logging cable 3, which is made in the form of a string stringed onto the logging cable and interconnected cylindrical elements. Cylindrical elements can be made with longitudinal grooves for cable passage through them or in the form of pipe segments or solid cylinders. Moreover, they have a constant cross section along the entire length and are made without any couplings or thickenings, contractions, etc. and are mounted on the cable using special clamps. The total length L of the displacer assembly is:
L = (h _p + h _k ) + (l _ds + l _dp ) + (h _d - h _st ),
where h _p - the depth of the sole of the reservoir, m;
h _to - the depth of the roof of the reservoir, m;
l _ds - the length of the additional flat cable, m;
l _DP - the length of the additionally raised cable, m;
h _d - the depth of the dynamic liquid level, m;
h _article - the depth of the static liquid level, m

The difference h _p - h _k is the length of the filter portion of the column, i.e. interval of depths in which the inflow profile should be studied. The length of the additional deflated cable l _ds (cable bypass) is necessary so that after the start of the displacer movement in the well, a constant dynamic level and, accordingly, a constant flow of liquid are established. Therefore, when the flowmeter approaches the bottom of the reservoir, the flow rate is already stabilizing. The length of the additional cable lift l _dp (cable re-raising) is necessary so that after passing through the filter interval the flowmeter clearly fixes the non-perforated column, thereby ensuring control of the quality of measurements. The total length l _ds + l _dp should be 20-30 m, although depending on the specific well conditions: integrity, deformation, clogging of the column, etc., it can vary. The difference h _d - h _article takes into account the change in the depth of the liquid level in the well during the measurement process. The displacer 5 is mounted on the cable so that its upper end is spaced from the flow meter at a distance R equal to:
R = h _p - h _st + l _ds .

 With this distance R, at the moment of the beginning of the flow meter registration, the upper end of the displacer is at the depth of the static liquid level in the well (see drawing).

The cross-sectional area S of the displacer 5 is selected based on specific downhole conditions. To this end, cylindrical elements of different cross sections are provided in the device kit. The determination of the required cross-sectional area of the cylindrical elements of the displacer is carried out by calculation by the formula:
S = q / V,
where q is the specified flow rate of the fluid along the wellbore, m ³ / h;
V is the speed of continuous recording flow meter, m / h

The predetermined flow rate of the wellbore q is usually taken close to the actual flow rate (flow rate) under normal operating conditions of the well. Depending on the type and inertia of the flow meter, the registration speed of the flow meter is 100-200 m / h. For example, at a given flow rate of the fluid along the wellbore q = 0.5 m ³ / h and flow rate registration rate V = 200 m / h, the cross-sectional area of the displacer elements should be:
S = q / V = 0.5 / 200 = 0.0025 m ² .

Таким образом для рассматриваемого примера требуется вытеснитель из цилиндрических элементов в виде сплошного цилиндра диаметром 56 мм.When using cylindrical elements in the form of a continuous cylinder, the diameter of the element should be:

Thus, for this example, a displacer from cylindrical elements in the form of a continuous cylinder with a diameter of 56 mm is required.

 The proposed device operates as follows.

Initially, in the well 1 below the reservoir 2, the additional length of the flat cable l _{ds is} lowered on the logging cable 3 to the flowmeter 4 with the displacer 5 fixed above the flowmeter to the logging cable 3. At the same time, the upper end of the displacer 5 is at a depth of the static liquid level in the well, and the flowmeter 4 is located below the bottom of the reservoir 2 by the length of the additional flat cable l _ds . Next, the cable is lifted and the flowmeter is recorded at a given constant speed V. The flowmeter 4 begins to move along the wellbore 1, approaching the bottom of the productive formation 2. At the same time, the upper end of the displacer 5 comes out from under the fluid level, releasing the volume of the well, which is filled with the fluid flowing in from the reservoir. At the same time, the liquid level in the well decreases to a depth normal for this speed of ascent of the displacer 5 of the dynamic level and a predetermined flow rate is established. The stability of the fluid flow in the wellbore 1 is ensured by the constant lifting speed of the logging cable 3. Next, the flow meter 3 moves along the interval of the filter of the formation 2, registering the inflow profile. After that, the flow meter 4 moves along the well string 1 above the reservoir 2. When the flow meter 4 moves away from the roof of the reservoir 2 by a distance corresponding to the length of the additionally raised cable l _dp , the lower end of the displacer 5 leaves the liquid level and registration of the flowmeter ends.

 The implementation of the proposed device will improve the accuracy, productivity and reduce the cost of flow metering wells.

Claims (1)

A device for researching wells, comprising a flow meter lowered into a well on a wireline cable with a fluid displacer fixed above the flowmeter on the cable, characterized in that the displacer is made in the form of a string stringed onto the wireline and connected to each other by cylindrical elements with a total length L of
L = (h _p - h _k ) + (l _ds + l _dp ) + (h _d - h _st ),
where h _p - the depth of the sole of the reservoir, m;
h _to - the depth of the roof of the reservoir, m;
l _ds - the length of the additional flat cable, m;
l _DP - the length of the additionally raised cable, m;
h _d - the depth of the dynamic liquid level, m;
h _article - the depth of the static liquid level, m,
moreover, the displacer is mounted on the cable so that its upper end is spaced from the flow meter at a distance R equal to
R = h _p - h _st + l _ds , m,
and the cross-sectional area S of the displacer elements is constant over the entire length and is selected depending on the specified flow rate and the speed of registration of the flow meter according to the formula
S = q / V,
where q is the specified flow rate of the fluid along the wellbore, m ³ ;
V is the speed of continuous recording flow meter, m / h