SU1737108A1 - Method for determination of fluid passage in annulus - Google Patents

Abstract

Use: oil for industry, geophysical methods for well testing, for thermometric surveys of wells in the process of their testing and development. SUMMARY: A background thermogram is recorded in an idle well, overlapped downstream of the perforated formation in the interval of possible annular fluid movement, the well is started, the temperature is measured below the overlap area, after receiving the signal from the annulus through the annulus the bottomhole is opened and produced The registration of the temperature in the sump, the change of which below and above the area of the overlap is judged by the annular movement of the fluid. 3 il. yo

Description

The invention relates to geophysical methods for well testing and can be used in thermometric well surveys in the process of testing and mastering them.

A known method for determining the annular fluid movement in a long-running well by recording a thermogram in the interval of the reservoir. The disadvantage of the method is its impossibility to use it after the start-up of the well, when the temperature field in the well is non-stationary.

Most closely related to the technical essence and the achieved result to the considered one is the method of determining the annular motion of a fluid by registering the temperature change in the sump

after starting the well. The presence of annular fluid movement is judged by the increased rate of establishment of the thermal floor in the sump, resulting in a disturbed temperature field in the interval below the perforated formation. The method is implemented in the initial stage of well operation, i.e. after its launch.

A disadvantage of the known method is the ambiguity of determining the annular flow of fluid under the conditions of gravitational convection in the sump (in the case of / Comp.), Which leads to similar temperature changes in the interval under study. Here / Ep./Eskv- density of the fluid, respectively, the reservoir and located in the well. The contribution of convection to the temperature distribution is particularly significant immediately after the launch.

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wells that takes place during testing and development of the well.

The purpose of the invention is to improve the accuracy and efficiency of the method due to the possibility of separating temperature anomalies due to gravitational convection.

The goal is achieved by the fact that in a known method for determining fluid behind-the-barrel movement, including recording a background thermogram in an idle well, measuring the temperature change in the sump after starting the well and determining the behind-the-barrel fluid thermogram after the start of the well, the overlap of the bottom below the perforated formation in the interval of possible annular fluid movement, while measuring the temperature change is carried out After the sensor of the thermometer receives a signal from the legacy space, the face is opened and the temperature in the sump is recorded and, by changing it, the behind-the-barrel movement of the liquid is detected below and above the overlap area.

The essence of the proposed method is based on the possibility of taking into account and eliminating the influence of gravitational convection when detecting intervals of behind-the-crown fluid flow according to thermometry data in compressor testing and development of oil wells. The emergence of gravitational convection in the well conditions is associated with a non-uniformity of the field of densities, when the more dense fluid layers are in the gravitational field higher than the less dense, i.e., / Ell / eSq (Fig.Cha). Here curves 1–4 are recorded, respectively, in 5; 20; 60 and 120 minutes after the start of the well. Examples of such a situation may be cases of cooling of the reservoir with injected waters or when a fluid with a higher mineralization is obtained from the reservoir compared to the fluid in the well after flushing it, etc. The distortion of the thermal field is similar to the change associated with ringhole movement (Fig. 16) . Since in both cases the violation of the temperature field is of the same nature, the separation of the gravitational convection from the annular flow is quite a challenge, especially in the conditions of their joint manifestation. The gravitational movement in a vertical well is directed downwards, therefore, such movement is possible when the wellbore is blocked below a perforated formation, for example, controlled by a packer or other devices. With the start of the well and in the absence of flow

the column thermal field in the sump interval below the packer will be determined by the heat transfer from the working formation (Fig. 1B). Curves 1-4 are registered, respectively, in 5; 60; 120 and 240 min after start

wells. For real time of testing or well completion (3-4 hours), the zone of thermal anomaly distribution by conductive heat conduction will be significantly less than 1 m. In the presence of a flow

behind the column, the nature of the violation of the initial temperature distribution will be determined by convective heat transfer when the fluid is throttled all the way. A change in the temperature in the well is observed throughout the entire interval of the annular flow (Fig. 16) and occurs by conductive heat transfer in the radial direction. Curves 1-4 are registered after 5; 60;

180 and 240 min, respectively, after the start-up of the well. When the packer is opened, the thermometer sensor will be located on the well axis, and in order to detect, for the first time, ringing, d r0 is necessary, where d is the distance from the packer to the temperature sensor; r0 - well radius. Time of approach of the temperature signal from the overflow channel to the thermometer sensor after the start-up of the well

is determined by the distance from the channel to the sensor and the thermal diffusivity of the medium filling the well, the distance to the temperature sensor (the sensor, when the bottom is closed, is on the axis

well) is determined by where the flow of the flowing fluid occurs. The most unfavorable in time setting temperature case (the most remote channel), when the movement goes

between cement and rock. If the diameter of the casing die is 146 mm, and consequently, the diameter of the dCKB well is 168 mm, then the distance to the sensor is 84 mm 0.084 m. The thermal diffusivity of the fluid filling the well is 0 m2 / h. Experience shows that the most frequent amount of heating of the liquid flowing past the column is AT0 1 ° C. A registered AT anomaly is considered to be reliable, amounting to 10% of the maximum, i.e. with respect equal to

- that - 0.1. Based on this and using the curves in FIG. 2 reflecting the nature of the formation of the temperature field over the cross section of the well with an annular flow, it is possible to determine the time after which the bottomhole should be opened and the thermograms should be recorded in the open borehole (the numbers here

No Fourier parameter F0 -j-). In this case, this time will be 0.08 rVa, or 1.4 hours. In case the flow flows between the column and the cement, then 0.7 h. In the absence of flow, as indicated above, the temperature signal detected by the temperature sensor will be due to heat transfer from the working reservoir in the vertical direction, while the signal arrival time will be much longer than with movement behind the column, and often neglected. Wire temporary measurements in the blocked and open wellbore and compared the results obtained, it is possible to detect with sufficient accuracy the annular flow, eliminating the ambiguity associated with the effect of gravitational convection.

The method is carried out as follows.

A background thermogram is recorded in an idle well. Before starting the well, the thermometer is set below the perforation interval and the overlap of the bottom is carried out in the interval of possible fluid movement behind the column, i.e. between a non-perforated aquifer and a perforated formation. Thereafter, the well is started and the temperature change below the overlap area is recorded. After the temperature signal from the annular space reaches the thermometer sensor, the face is opened and the temperature change in the sump is measured again. By the nature of the temperature change before and after the overlap of the bottom, the existence of annular flow is judged.

The method is implemented in laboratory conditions on a well model in accordance with the claims. On fig.Z presents the temperature curves: 1 - background before the start of the well; 2,3- after start-up with blocked bottom after the time necessary for the temperature signal to come from the annular space to the thermometer sensor; 4 - after opening the hole; 5, b - characterize the temperature change above and below the overlap by comparison. All possible situations of manifestation of certain processes determining the temperature field in the sump of the well are considered.

In the case when the gravitational convection and the circulating fluid circulation (Fig. 3a) are absent in the well, the thermal field in the sump of the well is formed only due to the heat transfer from the working formation. Curves 2–4 are recorded in 0.5; 1.5 and 3 hours after the start of the well. At the same time, the temperature at the observation points located above and below the overlap, respectively (and the upper point is not covered by the impact of

5 layer), does not change and remains constant both when it is closed and when the bottomhole is open. This is illustrated by the graph presented in the third column (curves 5 and 6). If the column circulation existed and there was no convection (Fig. 3b), the zone of disturbance of the initial thermal field covers the entire range of fluid flow behind the column. Since there is no fluid movement in the well itself,

5, the application of the overlap, as in the first case, does not affect the temperature formation process. On all curves (2-4), the annular flow interval is fully observed, only a change in temperature is observed.

0 in time. Curves 2 and 3 are registered, respectively, 0.5 and 1.5 hours after the start-up of the well. Immediately after the registration of curve 3, the face was opened. Curve 4 is registered 3 hours after the start of the well.

5 Temperature changes above and below the overlap are associated only with conductive, ie, heat transfer in the radial direction, curves 5 and 6 determine the nature of the temperature setting, respectively, above and

0 below the overlap, while the differences with the case Za are clearly visible.

If there is no annular flow, but only gravity convection exists (Fig. 3b), then in the region above, blocking the fluid movement in the well leads almost immediately after the start to an abrupt temperature change, and the temperature in this region becomes equal to the reservoir. Below the overlap, the thermal field is formed by conductive heat transfer in the vertical direction. Curves 2 and 3 are registered after 0.5 and 1.5 hours after the start-up of the well. After registration of curve 3, the bottomhole was discovered, which, due to the presence of gravity, led to more intense heat transfer in this region. Curve 4 is registered 3 hours after the start of the well. Comparison of curves 5 and 6, which characterize the change in temperature above and below the overlap, makes it possible to determine if only gravity convection is present in the well.

In case of joint manifestation of behind-the-ring circulation and gravitational convection, temperature disturbance occurs in the range of action of these processes (Fig. 3d). Curves 2 and 3 were obtained, respectively, 0.5 and 1.5 hours after the start-up of the well. After recording thermogram 3, the face was opened. Curve 4 is registered 3 hours after the start of the well. The differences in temperature variation above and below the overlap (curves 5 and 6) against the background of the existence of gravitational convection determine the presence of a cross-flow.

Thus, the proposed method for determining the annular motion allows to GROW the accuracy and efficiency of determining the cause of the disturbance of the temperature field in the sump of the well and unambiguously identify the presence of annular flow. To implement the method, highly sensitive thermometers with a special device to shut off the barrel are required.

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Claims (1)

Invention Formula A method for determining fluid behind-hole movement during well development, including recording a background thermogram in an idle well, measuring the temperature change in a sump after starting a well, and detecting behind-the-barrel fluid movement based on measurement results, which, in order to improve the accuracy and efficiency of the method, after registering the background thermograms before starting the well produce an overlap of the bottom below the perforated formation in the interval of possible annular fluid movement, while renie temperature change is carried out below the overlap region, after receiving the sensor signal from the thermometer annulus face opening and making the temperature T registered in the sump, wherein the change above and below the overlap region is judged on the annulus fluid movement. ffi 2.0 6 Fy with ABOUT g-t gS-S5