A drilling installation constituted by drill strings enabling information to be transmitted between the bottom of a borehole being drilled and the surface of the ground is already described in French patent 2 777 594 in the name of the Applicant. As explained in that document, while a borehole is being drilled, it is very important to be able to transmit to the surface information that is collected by sensors mounted in the vicinity of the drilling tool, which tool is fixed to the bottom end of the drill string.
One of the solutions proposed in the above-mentioned French patent is described below with reference to accompanying FIG. 1.
Because of the presence of the insulating layer 16, a closed current loop is established constituted firstly through the drilling mud 30 filling the inside of the rod 10 and secondly through the assembly constituted by the wall of the rod 10 and by the mud 32 outside the rod 10.
Using the bottom coil 24, alternating current (AC) representing information is induced in the current loop, with this AC being picked up by the receiver coil 26.
Such a installation for transmitting information via a drill string gives satisfactory results in some situations. Nevertheless, it will be understood that information is transmitted via two electromagnetic couplings corresponding to the two coils or toruses which are disposed respectively close to the top end of the drill string and close to its bottom end carrying the tool. These two couplings, constituting current transformers, present the particular characteristic of comprising a very large number of turns wound on toruses. In contrast, the other element of the coupling is constituted by a single turn and consists in the single current loop established essentially via the mud contained in the drill string. Electromagnetic coupling of that type is not optimal and its efficiency or effectiveness can turn out to be insufficient, particularly when the electrical conductivity of the mud is low.
An object of the present invention is to provide a drill string of the above-mentioned type which is fitted with means for transmitting information between the bottom of the borehole in which the equipment is to be found and the ground surface, which drill string enables information transmission to be improved, particularly at the interface between the transmitter or receiver and the mud used for conveying the information.
According to the invention, this object is achieved by a drill string fitted with information transmission means comprising:
a plurality of hollow rods made of conductive material, the inside faces of said rods being covered in insulating material;
a drilling tool secured to the bottom rod of the drill string, said drill string being disposed in part in a borehole filled with an electrically conductive mud, said mud inside the drill string and the mud outside the drill string together with the drill string itself forming a closed loop that conducts electricity;
a first electrical unit placed close to the bottom end of the drill string, in order at least to create in said loop an electrical current representative of information to be transmitted; and
a second electrical unit placed in said borehole, close to the top end of the drill string, in order at least to receive the information contained in said electrical current.
The drill string is characterized in that said first electrical unit comprises at least a first annular electrode secured to the insulating inside face of the drill string, said electrode being in electrical contact with the mud contained inside the drill string; and
means for applying to said electrode a voltage that is representative of said information to be transmitted.
It will be understood that according to the invention the information for transmission is applied in the form of a voltage to the annular transmitter electrode disposed at the bottom end of the drill string. Relative to ground, this voltage induces current in the above-defined closed current loop, said current being modulated as a function of the information to be transmitted. Reception at the top end of the drill string can be performed as in the above-mentioned state of the art by means of an electromagnetic coupling coil placed inside the drill string, said coil surrounding the mud contained in the drill string, which mud conveys the current.
A second solution of the invention consists in placing two conductive electrodes that are axially offset on the insulating inside face of a rod located close to the top end of the drill string. The potential difference which appears between the two electrodes is created by the current flowing in the current loop. This potential difference is thus itself modulated in the same manner as the current, as a function of the received information.
In a more complete version, the electrical unit placed at the bottom end of the drill string and the electrical unit placed at the top end of the drill string can both be constituted by two conductive electrodes mounted inside the insulating inside face of the rods. Alternatively, one of the electrodes can be used as a transmitter for transmitting information and both electrodes can serve in alternation as receivers of the information that is to be transmitted.
Other characteristics and advantages of the invention will appear better on reading the following description of various embodiments of the invention given as non-limiting examples. The description refers to the accompanying drawings, in which:
With reference initially to
As already explained, the borehole 40 is filled with a mud that conducts electricity more or less well and that fills not only the inside 46 of the drill string, but also the annular space 48 between the drill string and the wall of the borehole 40. This establishes a closed conductive loop constituted firstly by the mud on the inside 46 and secondly by the conductive wall 42 together with the mud in the outer annular space 48. These two branches of the electrically conductive circuit are separated by the insulating layer 44 and they are interconnected at the bottom by the tool itself and at the top by appropriate means. In this figure, reference 40F designates the borehole and 40S the top end of the borehole close to the surface of the ground S.
According to an essential characteristic of the invention, the bottom electrical unit is constituted by an electrode, preferably an annular electrode 50, which is fixed by any suitable means to the insulating wall 44 of the rod Ti. This electrode is in direct electrical contact with the mud 46 contained inside the drill string. The electrode is preferably disposed at a sufficient distance from the drilling tool. Similarly, at the top end of the drill string, there can be seen an electromagnetic coupling coil 52. It will be understood that in order to transmit information from the bottom of the borehole close to the tool towards the top portion of the borehole, i.e. towards the surface of the ground, a modulated electrical voltage is applied to the electrode 50, with the modulation corresponding to the information that is to be transmitted. This electrical voltage sets up a modulated electrical current in the zone 46 which flows around the above-defined current loop. This current passes in particular through the zone surrounded by the electromagnetic coil 52. The flow of this modulated current causes an electrical voltage to appear at the terminals of the coil 52, which voltage is representative of the information transmitted by the electrode 50. It will be understood that this avoids the above-mentioned problems concerning transmission and corresponding to poor electromagnetic coupling between the current loop and the coil as provided in the prior art for sending the information. However, such poor quality coupling is less unfavorable when it comes to reception by the electromagnetic coil 52.
In some cases, it is useful to transmit information not only from the bottom of the borehole to the surface of the ground, but also from the surface of the ground down to the bottom of the borehole, e.g. to send information to actuators of the drilling tool. To achieve this result, a second annular electrode 54 is provided in the bottom rod Ti where it is fixed to the insulating wall 44 of the rod. The electrode 54 is offset axially by a distance d relative to the transmitting electrode 50. When AC is applied to the coil 52, this induces current in the mud 46 which is modulated in the same manner and which flows around the above-defined current loop. This circulating current establishes a potential difference between the electrodes 50 and 54, which potential difference can be picked up and presents the same modulation as the current initially applied to the coil 52. By measuring the modulation of the potential difference between the electrodes 50 and 54, it is possible at the bottom of the borehole to pick up information transmitted by the coil 52.
Reference is now made to
During a transmission stage, i.e. when measurements made by the tool sensors are to be transmitted to the surface of the ground, the circuit 58 receives encoded information for transmission and they generate a corresponding electrical voltage for application to the transmission electrode 50, thereby injecting modulated current into the closed conductive loop.
During a reception stage, the circuits 58 are connected simultaneously to both electrodes 50 and 54. The circuits 58 have means for measuring the potential difference between the voltages picked up by the electrodes 50 and 54. This potential difference carries modulation corresponding to the received information which can be encoded or forwarded in suitable manner by the circuits 58 for application to actuators of the tool via the electrical connection 66.
In the embodiment of
In the figures, the annular electrodes are represented as projecting relative to the insulating layer 44. Preferably, the insulating layer 44 is of sufficient thickness to make it possible for the inside faces a of the electrodes to be flush with the inside face of the insulating layer. Nevertheless, it is necessary for the thickness of the portion of the insulating layer between the electrode and the wall of the rod to be sufficient to provide the desired degree of electrical insulation. This avoids creating head losses in the rod.
Also preferably, the annular electrode is made out of a material that is a good conductor of electricity, e.g. brass, having its inside surface treated, e.g. by nitriding, so as to give this surface sufficient hardness to enable it to withstand the abrasive effect of the liquid circulating in the rod.
The width l of the electrodes in the axial direction of the rod is preferably greater than or equal to 2D, where D is the inside diameter of the duct.
When the system is designed to operate as a receiver also, it is advantageous for the distance d between the two electrodes to be as great as possible. However, this distance is limited since, for manifest practical reasons, it is necessary for the two electrodes to be mounted on the same rod of the drill string. This distance therefore depends on the length of the bottom rod Ti and on the length of the top rod Ts.
Finally, tests have been performed which show that good signal transmission is obtained even for a drill string that is 80 meters long, when using an alternating electrical signal at 10 volts delivering about 50 milliamps.
Number | Date | Country | Kind |
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01 01067 | Jan 2001 | FR | national |
Number | Name | Date | Kind |
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3518609 | Fontenot, Jr. | Jun 1970 | A |
3866678 | Jeter | Feb 1975 | A |
4095865 | Denison et al. | Jun 1978 | A |
4483393 | More et al. | Nov 1984 | A |
4496203 | Meadows | Jan 1985 | A |
4575681 | Grosso et al. | Mar 1986 | A |
4578675 | MacLeod | Mar 1986 | A |
Number | Date | Country |
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0 295 178 | Jun 1988 | EP |
0 964 134 | Jun 1999 | EP |
2 777 594 | Apr 1998 | FR |
Number | Date | Country | |
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20020105334 A1 | Aug 2002 | US |