RU2375566C1 - Method and device for well video monitoring - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: invention refers to geology and predominantly is intended for deep-earth video monitoring. The method includes immersing the device or video monitoring into well, creating optically transparent segment in the area of video monitoring by pumping-in optically transparent liquid the density of which is selected being close to density of well liquid. During pumping-in the optically transparent liquid and video monitoring the area of video monitoring is limited by liquid stream spreader. The device contains tanks with optically transparent liquid, pump, control unit, umbilical with video instrument attached at its end and appliance for optically transparent liquid supply. Liquid stream spreader is installed on video instrument.

EFFECT: creation of method and device for video monitoring of well which in conjuction enable creation of stable optically transparent segment in the area of video monitoring.

6 cl, 4 dwg

Description

The invention relates to geology and is primarily intended for in-depth video surveillance, for example, during visual inspection and automated flaw detection of the state of boreholes.

In the process of drilling a well, producing oil and gas, it is often necessary to obtain real-time information about the condition inside the well. For example, obtaining data on the installation and / or operating conditions of the equipment located in the well to determine the onset of corrosion damage to the casing pipes, etc., in order to timely introduce anti-corrosion substances into the well. As well as during maintenance work on a production well, such as replacing various flow controllers or monitoring the position and condition of casing perforations. For this, various monitoring devices are used that comprise a video camera (US 5140319, publ. 1992, WO 9938315, publ. 1999). But the video surveillance process is complicated due to the opacity of the well fluid, therefore an optically transparent fluid is pumped into the surveillance zone, the density of which is selected as close as possible to the density of the well fluid to reduce gravitational mixing of the fluids.

For example, a well-known method for visual inspection of a well is known (US 4238158, IPC G01N 21/01, publ. 1980), which comprises forming an optically transparent section at the required depth by injecting an optically transparent liquid, which is previously prepared by mixing two or more liquid and / or solid components . After the formation of the optically transparent portion at the required depth, the observation device is lowered.

The disadvantage of this method is the destruction of the optically transparent area with the introduction of a device for observation, mixing the optically transparent and wellbore fluids and, as a result, reduced “visibility”. In addition, the density of the fluid is influenced by the ambient temperature, which can lead to a significant error in the alignment of the densities of the borehole and optically transparent fluids. Accurate accounting of these destabilizing factors is practically impossible, therefore, the processes of gravitational mixing are not eliminated only by selecting the density of liquids.

The closest is the method of visual examination of the well described in US patent 5419188, IPC ЕВВ 47/00, publ. 1995, which includes lowering the device for researching the well to a predetermined depth and then creating an optically transparent section by pumping into the observation zone an optically transparent fluid whose density is selected close to the density of the well fluid.

When an optically transparent liquid is injected directly into the observation zone under pressure, turbulent mixing of the injected and well fluid occurs, which occurs due to the relatively high jet velocity (of the order of 1 m / s) of the optically transparent liquid pumped through the umbilical (with a hose section of about 3-4 cm ² and productivity 1 m ³ / h). Turbulent mixing causes a decrease in transparency in the studied interval, as well as an increased consumption of optically transparent liquid and an increase in the time for downhole video recording.

The closest is a device (US 5419188, IPC Е21В 47/00, publ. 1995), containing reservoirs with an optically transparent liquid, a control unit, a pump, a umbilical, at the end of which there is a monitoring device and a device for pumping optically transparent liquid.

A disadvantage of the known device is the low degree of transparency in the studied interval with increased consumption of optically transparent fluid due to gravitational and turbulent mixing of the well fluid with an optically transparent fluid.

The objective of the described invention is to provide a method and device for video surveillance of the well, allowing to create a stable optically transparent area in the video surveillance zone.

The problem is solved due to the fact that the method of video surveillance of the well includes immersing the video surveillance device in the well, creating an optically transparent section in the video surveillance zone by pumping an optically transparent fluid, the density of which is selected close to the density of the well fluid. When pumping an optically transparent liquid and during video surveillance, the video surveillance zone is limited by a liquid flow separator.

The described method allows to stabilize an optically transparent area due to the restriction of the video surveillance zone, which prevents gravitational and turbulent mixing of liquids.

The problem is solved due to the fact that the video surveillance device for implementing the proposed method comprises reservoirs with an optically transparent liquid, a pump, a control unit, a umbilical, at the end of which a video device and an optical transparent liquid supply device are fixed. A video splitter separator is installed. The liquid flow separator can also be made in the form of an elastic hollow ring hydraulically connected to an optically transparent liquid supply device, which can be made in the form of hollow tubes. Moreover, the ends of the hollow tubes, on which the nozzles can be installed, are located below the liquid flow separator.

The described invention allows you to create a stable optically transparent area in the video surveillance area through the use of a separator of fluid flows.

Figure 1 - illustration of an experiment for pumping an optically transparent fluid without a separator of fluid flows into a cavity simulating a borehole with a borehole fluid.

Figure 2 is an illustration of an experiment for pumping an optically transparent fluid with a separator of fluid flows into a cavity simulating a well with a well fluid.

Figure 3 - device for video surveillance wells with an umbrella packer.

Figure 4 - a device for video surveillance of a well with a packer in the form of an elastic hollow ring.

Before video surveillance, a sample of the borehole fluid is taken, its density is determined, and the density of the optically transparent fluid is selected for injection into the well as close as possible to the borehole in order to avoid gravitational mixing of the fluid.

The video device is lowered on the umbilical to the point where it is necessary to carry out video surveillance - the video surveillance zone. The surveillance zone is limited by a separator of fluid flows. Further, an optically transparent fluid with a density close to the density of the borehole fluid is pumped through a umbilical and a special device into the video surveillance zone immediately before the video device. As a result, a stable optically transparent area is formed in the video surveillance zone.

An optically transparent liquid of the required density can be obtained by mixing various components, one of which is liquid. For example, two liquids of different densities or liquids and a dry component.

A series of experiments was carried out for which a well model was made, filled with simulated well fluid with an appropriate density. Figure 1 - the result of an attempt to create an optically transparent area in the proposed surveillance zone by injecting an optically transparent fluid with a density close to the wellbore fluid (first experiment). Figure 2 - the result of the experiment to create an optically transparent area in the proposed surveillance zone according to the described method (second experiment). Where the dark fluid is the imitation of the borehole fluid (plot A), the transparent plot is the one formed by the described method (plot B), the patch with the optically transparent fluid, and the gray fluid is the mixture of the optically transparent and well fluid that was formed as a result of mixing while pumping the first well layout (section B).

As can be seen from the results, in the first experiment, the supposed optically transparent region has a cloudy gray color, which indicates that there was a mixing of liquids. Mixing of the fluids caused poor visibility and increased consumption of the injected optically clear fluid. In the second experiment, the formed transparent region with good optical visibility is clearly visible.

Limiting the surveillance zone from the total mass of the well fluid before forming the optically transparent section can significantly reduce the effect of ambient temperature on the error in leveling the density between the well and the injected fluid and, as a result, reduce gravitational mixing. In addition, turbulent mixing of liquids is reduced, since the restriction of the video surveillance zone eliminates the mixing of fluid flows caused by the high speed of an optically transparent liquid pumped under pressure. Reducing the loss of injected fluid for gravitational and turbulent mixing also significantly reduced the flow of injected optically transparent fluid and reduce the time for preparing and conducting video surveillance.

A video surveillance device for implementing the described method comprises reservoirs 1, 2 and 3 (FIG. 3 and FIG. 4). Tank 1 - with an optically transparent liquid of reduced density, 2 - with an optically transparent liquid of increased density. The tank 3 for mixing liquids of different densities communicates with tanks 1, 2 and with the pump 4 through pipes and taps. Hose cable 5 is a hose 6, inside of which a logging geophysical cable 7 passes. At the end of the umbilical, by means of a fastener 10, a video device 8 and a device for supplying optically transparent liquid 9, which can be made, for example, in the form of hollow tubes, are fixed. On the video device 8, a separator of fluid flows 11 is installed.

In a preferred embodiment of the invention, the separator of fluid flows is made in the form of an umbrella packer (figure 3). In another embodiment, it is in the form of an elastic hollow ring (Fig. 4), which can be made, for example, of rubber and capable of increasing the volume (opening) when liquid is injected into it. With this design, the device for supplying an optically transparent liquid in the form of hollow tubes is hydraulically connected to the elastic hollow ring via holes 12, and nozzles are installed at the ends of the tubes to create a working opening pressure in the elastic hollow ring.

The hose cable is placed on the drum 13 and the guide roller 14, which are mounted on the bed 15.

The functioning of the device for video surveillance, as well as fixing video surveillance is carried out by the control unit 16.

A device for video surveillance, in accordance with the described method, operates as follows.

In a preferred embodiment, when the device is made with a liquid flow separator in the form of an umbrella packer (Fig. 3), the video device 8 is lowered into the well 17, filled with a borehole, optically opaque liquid 18. When the video device reaches the surveillance zone 8, an umbrella packer is opened to reduce turbulent and gravitational mixing and using a pump 4 begin to pump an optically transparent liquid, which is pre-prepared in the tank 3 by mixing two liquids of different densities, coming from reservoirs 1 and 2. The density of the finished fluid is as close as possible to the density of the borehole fluid to prevent gravitational mixing of fluids. From the reservoir 3, the optically transparent liquid enters the pump 4, which directs it through the umbilical 5 to the device for supplying the optically transparent liquid 9 and then to the video surveillance zone directly in front of the video camera. Thus, a portion of the optically transparent liquid 19 is formed.

In another embodiment of the device, with a liquid flow separator in the form of an elastic hollow ring (Fig. 4), the device operates in a similar manner, except that the opening of the liquid flow separator occurs when an optically transparent liquid is supplied. When an optically transparent fluid passes through a hollow tube feed device, the jets provide a pressure differential of several atmospheres between the pressure in the feed device and the well fluid surrounding the video device. As a result, through the opening 12 of the supply device, liquid will begin to flow into the elastic hollow ring, opening it and restricting the video surveillance zone.

The described method, as well as a device for its implementation, allows you to create a stable optically transparent section in the video surveillance zone by eliminating the gravitational and turbulent mixing of the borehole and optically transparent liquid while restricting the video surveillance zone using a liquid flow splitter. Reducing the loss of injected optically transparent liquid for gravitational and turbulent mixing also allowed to reduce the consumption of optically transparent liquid and reduce the time for preparing and conducting video surveillance.

Claims (6)

1. A method of video surveillance of a well, comprising immersing a video surveillance device in a well, creating an optically transparent portion in the surveillance zone by pumping an optically transparent fluid, the density of which is selected close to the density of the well fluid, characterized in that when pumping the optically transparent fluid and during the video surveillance process, the area CCTV is limited by a separator of fluid flows. 2. The video surveillance device for implementing the method according to claim 1, comprising reservoirs with an optically transparent liquid, a pump, a control unit, a umbilical, at the end of which is mounted a video device and an optical transparent liquid supply device, characterized in that a liquid separator is installed on the video device. 3. The device according to claim 2, characterized in that the separator of fluid flows is made in the form of a packer. 4. The device according to claim 3, characterized in that the packer is made umbrella. 5. The device according to claim 2, characterized in that the optically transparent liquid supply device is made in the form of hollow tubes, the ends of which are located below the liquid flow separator. 6. The device according to claim 5, characterized in that the packer is made in the form of an elastic hollow ring, which is hydraulically connected with hollow tubes, at the ends of which there are additional nozzles.

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