SU842191A1 - Deep-well complex device for hydrodynamics and hydrophysics studies - Google Patents

Description

(54) COMPLETE BOTTOM. DEVICE. FOR HYDRODYNAMIC AND GEOPHYSICAL RESEARCHES

Zanniy with probe-sensor, and in the axial channel of the lock device are placed the differential valve and the valve-valve, interacting with the differential valve and with the probe-sensor, and the cavity ngSH | the differential spool is connected with the well space, and the cavity under the differential spool through the axial channel of the body of the sluice device - .9 in-line space.

1 shows a lock device of a packer system; in Fig.2 a cut of A-L in Fig.1; FIG. 3 shows a downhole downhole tool with a probe sensor.

Shlzazovoe device contains a tubular body 1 with an axial channel, scrap 2, force channel 3, side balancing hole 4, valve 5, differential valve b with longitudinal notches 7, rotary valve plug 8 with pins 9, lug 10 and side hole 11, as well as fixed stop 12. The axial channel has an annular recess 13.

The downhole tool includes a housing 14, suspended from geophysical-. com cable 15, seals 16, inlet channel 17 with electrically controlled / 1 valve 18. Probe sensor 20 is suspended to the casing of the downhole tool on cable 19, which has a possibility of longitudinal movement along cable 19. The downhole tool also has spring-loaded clips 21 for fixing it in the channel of the lock device, the Packer system consists of a packer 22 a box 23 and an axial channel. a packer 24

U-system works as follows.

The sluice device, which has through axial channels for the passage of the formation fluid and passing the probe sensor through them, is lowered to the well at the required depth on empty pipes. At that, the axial channel; (consequently, the pipe cavity) is sealed with a valve-plug 8, and the channel 3 is filled with liquid. Downhole tools are lowered into the pipes 15, the housing 14 of which with seals 16 enters the axial channel of the valve 5 and overlaps it 4. Clamps 21 upshots in the recess 13, fixing the casing of the downhole tool from the release of peredal pressure between the well and in-line spaces. At the same time, the case of the squash device moves the valve 5 down, opening the communication of channel 3 through channel 2 with the internal cavity of the pipes. At the same time, the probe sensor 20 rests on the plug 8, moving upward relative to the cable 19.

After opening channel 3, the differential valve 6 moves downward under the action of the pressure difference in the well and inside the pipes. At the same time, the opening 4 is opened first and the pressure above the stopper 8 is equalized with the pressure under it, and with further movement of the spool 6, the upper edges of the notch 7 at the spool, abutting the trunnions of the stopper 9, 8, pull the last axial channel 2. After that 10 abut against the stop 12, as a result of which the stopper 8 rotates downward by 90, so that its side opening 4 coincides with the axial channel 2. Under the action of gravity, the probe sensor 20 goes down and extends beyond the lock device, the packer and the root device.

After that, the entire device is ready for hydrodynamic surveys, which are carried out after packing by opening and closing the electrically controlled valve 18 of the downhole tool, and geophysical surveys using the probe sensor 20 by longitudinal displacements of the entire string of pipes to the wellbore. At the same time, all information from the downhole tool is transmitted to the surface recording equipment via cable 19. Due to the fact that the measuring equipment is assembled and connected to the cable completely outside the well, all the electrical connections are completely reliable, which prevents the device from re-descending into the well from - due to possible faults, the same applies to the possibility of controlling the valve 18 by electrical signals over the cable.

The ability to use pipes as a sampling tank significantly increases the efficiency of the comp method: lexing geophysical and hydrodynamic studies, as it increases their accuracy and reliability. .

The application of the proposed device allows to reduce the volume of well testing by pipe testers and the volume of geophysical studies, as well as to increase the reliability of research results.

Cost efficiency is calculated only to reduce the amount of testing of wells in pipe testers. At the same time, the cost of one trial is 1300 r. During the year, the device is used 50 times. If accepted, when using

Claims (1)

Claim An integrated borehole device for hydrodynamic and geophysical surveys containing a packer system with an axial channel, an electric transducer, a downhole tool and a logging probe, characterized in that, in order to increase the reliability of the studies, it is equipped with a lock assembly made in the form of a tubular housing with an axial and power channels and a differential valve, forming a chamber with the housing connected through a power channel and a valve with an axial channel, the axial channel of the housing being blocked at the bottom of the a sample valve with a longitudinal channel interacting with a differential spool, with the possibility of communicating a longitudinal channel with the axial channel of the body at the lower position of the valve, and the body of the downhole tool _ has a supply channel with an electrically operated valve and is connected using a cable with a logging probe.