DE102014102906A1 - Underground detection device and detection method - Google Patents

Abstract

The invention relates to a downhole detection device (or a visualization device) and a detection method for cased and uncased holes in the ground (hereinafter referred to as "hole"), especially when the downhole liquid is not translucent and / or cloudy. In order to provide a detection device and a detection method for drilling, which make it possible to detect obstructions, corrosion damage, dimensions, burst and the type of rock in the bore itself and the dimension of the oil or gas deposit and the wall and the fluid present there, is proposed in the invention that a probe is provided, which can be guided through the bore, wherein the probe has at least one ultrasonic transmitter and at least one ultrasonic receiver and an evaluation unit is provided.

Description

The invention relates to a downhole detection device (or a visualization device) and a detection method for cased and uncased holes in the ground (hereinafter referred to as "hole"), especially when the downhole liquid is not translucent and / or cloudy.

The prior art is the introduction of an optical camera to get an image of the underground situation. The main disadvantage is that this only works in a clear translucent liquid.

If an underground tool or device accidentally remains in a hole, then it must be removed from the hole. The standard procedure is to drive a device into the well, e.g. by means of a drill string or endless tube or steel cable, to the tool or device, which connects to this remaining tool or device so that it can be removed from the bore. For this purpose, each tool or device has a standardized device on the top, which allows a coupling. But if now this remaining tool or device is so damaged that a coupling is not possible, then a lead block is used in the prior art, which is discharged into the bore and hits the obstruction. The resulting impression in the lead block is then analyzed. This is disadvantageous in that only a superficial detection / impression is possible - if at all - and gravity or an axial force is required to produce the impression. The size of the obstruction and its spatial formation can hardly be determined. Another method is the use of optical cameras, the achievable recordings for multiple purposes, such. As the detection of constrictions in a hole (eg caused by collapse of the bore) or growth of minerals and / or wax, pipe break or corrosion damage serve. All this is only possible if the liquid in the bore is optically transparent. A correct 3D representation of an obstruction with an optical camera is in need of interpretation and therefore not always accurate.

Also, fluid types in the bore can not be determined and also the position of the obstruction in a non-cased hole can only be estimated by cable length or rod length.

For example, to determine the dimension of an underground oil deposit, mechanical arms are deployed that extend through the well into the oil well, and an angle analysis of the arms determines the diameter of the oil deposit. The range of such arms and the number of possible measuring points are limited, so that at best an approximate dimension determination is possible. Furthermore, there is the risk of damaging the mechanical parts and there is also no information about the wall of the oil reservoir, for example, the rock type, as well as determined by the nature of the fluid present therein.

The object of the invention is to provide a detection device and a detection method for drilling, which make it possible obstructions, corrosion damage, dimensions, pipe breakage and the type of rock in the bore itself and the dimension of the oil or gas deposits and the wall and the detect fluid present there.

This object is achieved with the detection device according to the invention in that a probe is provided, which can be guided through the bore, wherein the probe has at least one ultrasonic transmitter and at least one ultrasonic receiver and an evaluation unit is provided.

Due to the emission of signals in at least two dimensions, preferably in three dimensions, and the temporal measurement of reflection signals over such signal propagation times, which depend both on the path and the reflection surface, such an ultrasound probe can measure the respective one without contact and with high precision In addition, conclusions about material properties can be obtained from the reflection. It can thus measure objects, obstructions and cavities as well as the spatial extent of an oil deposit and create 3D images using vectors and also determine rock types and fluid compositions. The means for evaluating the measured data can be arranged both in the probe and in an external evaluation unit.

It is inventively provided that the probe by means of a drill string, a cable, by coupling to an endless tube, by feeding gases or liquids or, for example, in the case of a horizontal or steeply inclined bore, by means of a pipe or cable mounted traction device through the hole can be guided through.

With the above-mentioned technical devices, the probe can be controlled drained through the hole and pulled back up. It is both an active drive of the probe, for example via a traction device, possible as well as a passive drive, for example, by the probe is guided by the introduction of gases or liquids through the bore.

It can be provided that means are provided for coupling and uncoupling the probe to the cable.

A development of the invention is that the probe has a drive. The probe may travel within a space via a drive, which may for example be designed as wheels, chains or rollers for moving the probe in the bore or at the bottom of an oil deposit or at least one propeller or a jet propulsion in a buoyant probe, to make detections there. The drive can be arranged on the probe itself or a separate drive can be coupled to the probe.

An advantageous development of the invention is that the or the ultrasonic transmitter and the or the ultrasonic receiver are designed for one, two or three-dimensional measurement.

The two- and three-dimensional measurements can be made possible by separate ultrasound transmitters and receivers for each direction or else the diversion and separate evaluation of the ultrasound signal or the reflection signal. Another possibility is to use only one probe, but which is movable and thus can perform a two- or three-dimensional detection. With a one-dimensional measurement, it is possible, for example, to determine distances to the probe, rock types, fluid compositions and also flow velocities of fluids. The two-dimensional measurement enables a two-dimensional determination, the three-dimensional measurement a determination of spatial geometries. Accordingly, one, two or three-dimensional representations can be generated based on the measurement data.

A preferred embodiment of the invention is that means for determining the position of the probe are provided.

In the presence of such means, it is possible to detect the location of particular objects, areas or spaces relative to the current position of the probe.

In this context, it is advantageous that the means for determining the position comprise an acceleration sensor or a gyroscope.

A development of the invention is that means for determining the speed of sound are provided.

Although it is possible to estimate the speed of sound, which with approximate knowledge of the possible composition of the fluid, in particular the mineral content, and the temperature of the fluid can lead to a good approximation. However, it is preferable to measure at least one parameter, such as the temperature of the fluid, and to approximate the sound velocity using this parameter. Optimally, the probe has means for determining the speed of sound in which a transit time is determined over a defined measuring path.

Furthermore, it is expedient that means for transmitting the measurement data or the result of the evaluation from the probe to a receiving unit are provided.

This makes it possible to evaluate the measurement data or the result of the evaluation during the current measurement, for example, to decide whether the measurement is continued, interrupted or terminated. The measurement data or the result of the evaluation can be transmitted, for example via a cable or wireless transmission to the receiving unit. In the latter case, it is possible, for example, to provide relay units in the region of the cable which, if appropriate, amplify the received signals and transmit them further.

The object is achieved in the detection method according to the invention in that a probe according to the invention is passed through the bore, wherein the probe has at least one ultrasonic transmitter and at least one ultrasonic receiver and wherein the signals emitted by the at least one ultrasonic transmitter received and evaluated as reflection signals from the ultrasonic receiver become.

With such a probe, distances, areas or spatial geometries can be determined in the area of the well and also in the area of the oil deposit into which the bore opens, and the composition of materials and liquids can be determined.

An embodiment of the invention will be explained in more detail with reference to drawings.

Show it

1 a schematic representation of the use of a detection device according to the invention in a bore,

2 a schematic representation of the measurement and evaluation process in the detection device according to the invention.

In 1 is a hole 1 represented, which, as it often occurs in practice, not exactly in the vertical direction. In this hole is an obstruction object 2 in the form of a pipe section 2 that remained in the hole ..

To detect what type of obstruction object 2 it is, a detection device according to the invention is used, which is a probe 3 which passes through the hole 1 can be guided through and has at least one ultrasonic transmitter and at least one ultrasonic receiver and an evaluation unit.

It can be seen that the probe 3 via a cable, for example 4 through the hole 1 can be guided through.

The probe 3 is introduced with eg the cable to the obstruction object and by the or the ultrasonic transmitter and the or the ultrasonic receiver a one-, two- or three-dimensional measurement performed. Due to the transit time between the emission of the ultrasound signal and the detection of the corresponding reflection signal, both the position relative to the probe and the type of obstruction object can be known in the evaluation unit at a known sound velocity 2 be determined. To get a precise result in the transit time determination, the probe points 3 Means for determining the speed of sound, in which a runtime is determined over a defined measuring path.

Indicates the probe 3 additional means for determining the position of the probe 3 On, for example, an acceleration sensor or a gyroscope, also the absolute position of the obstruction object 2 and its size are determined.

Likewise, it would be possible rock types, the Bohrlochwandgeometrie (cracks, fractures, etc.), fluid compositions, etc. in the bore 2 or in the area of an oil or gas deposit into which the well 2 flows to determine. The measurement data or the result of the evaluation, for example, via a cable from the probe 3 to a receiving unit 5 transmitted and there on a screen 6 be visualized.

2 shows schematically the detection method. In the probe 3 are three ultrasonic transmitters 7 arranged to emit the ultrasonic signals in three mutually perpendicular axes x, y, z. The corresponding reflection signals are from three ultrasonic receivers 8th detected and an evaluation 9 fed. The result of the evaluation is sent to the receiver unit 5 transmitted, which is located on the earth's surface. The movement of

probe 3 itself is provided by means for position determination 10 the probe 3 determined and as well as the ultrasonic transmitter 7 from a control unit 11 controlled.

Claims (10)

Detection device for cased and uncased bores into the soil, characterized in that a probe ( 3 ), which can be guided through bore, wherein the probe ( 3 ) at least one ultrasonic transmitter ( 7 ) and at least one ultrasonic receiver ( 8th ) and an evaluation unit ( 5 ) is provided. Detection device according to claim 1, characterized in that the probe ( 3 ), by means of a drill string, a cable, by coupling to an endless tube, by feeding in gases or liquids or by means of a traction device ( 4 ) through the cased and uncased bore area ( 1 ) is feasible. Detection device according to claim 2, characterized in that means for coupling and uncoupling the probe ( 3 ) to the cable ( 4 ) are provided. Detection device according to one of claims 1 to 3, characterized in that the probe ( 3 ) has a drive. Detection device according to one of claims 1 to 4, characterized in that the ultrasonic transmitter (s) ( 7 ) and the ultrasonic receiver (s) ( 8th ) are designed for one-, two- or three-dimensional measurement. Detection device according to one of claims 1 to 5, characterized in that means ( 10 ) are provided for determining the position of the probe. Detection device according to one of Claims 1 to 6, characterized in that the means ( 10 ) comprise an acceleration sensor or a gyroscope for position determination. Detection device according to one of claims 1 to 7, characterized in that means for determining the speed of sound are provided. Detection device according to one of claims 1 to 8, characterized in that means for transmitting the measurement data or the result of the evaluation from the probe ( 3 ) to a receiving unit ( 5 ) are provided. Detection method for cased and uncased holes in the ground, characterized in that a probe ( 3 ) according to one of claims 1 to 9 through the bore ( 1 ), whereby the probe ( 3 ) at least one ultrasonic transmitter ( 7 ) and at least one ultrasonic receiver ( 8th ) and wherein the of the at least one ultrasonic transmitter ( 7 ) emitted signals as reflection signals from the ultrasonic receiver ( 9 ) and in the evaluation unit ( 9 ) be evaluated.

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