Patent Abstract:
A compact, robust, wear resistant, and high performance electrically insulating gap sub for use with borehole EM Telemetry is disclosed. In one embodiment, the gap sub may include an externally threaded mandrel separated from an internally threaded housing by a dielectric material. Additionally, some embodiments may include an external gap ring for separating the upper and lower electrical halves of the sub which offers structural support, acts as the primary external seal, and provides an abrasion resistant non-conductive length on the exterior. Some embodiments may include torsion pins to prevent the possible unscrewing of the dielectric filled threaded sections should the dielectric material become damaged or weakened.

Full Description:
CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     This application claims priority to U.S. Provisional Patent Application Ser. No. 60/491,569, filed Jul. 31, 2003.  
         [0002]     This application is a continuation-in-part of co-pending U.S. patent application Ser. No. 10/744,683, filed Dec. 23, 2003. U.S. patent application Ser. No. 10/744,683 is a continuation of U.S. patent application Ser. No. 10/161,310, filed Jun. 3, 2002. U.S. patent application Ser. No. 10/161,310 has issued as U.S. Pat. No. 6,672,383. U.S. patent application Ser. No. 10/161,310 is a divisional of U.S. patent application Ser. No. 09/777,090, filed on Feb. 5, 2001. U.S. patent application Ser. No. 09/777,090 has issued as U.S. Pat. No. 6,405,795. U.S. patent application Ser. No. 09/777,090 is a divisional of U.S. patent application Ser. No. 08/981,070, filed Dec. 10, 1997. U.S. patent application Ser. No. 08/981,070 has issued as U.S. Pat. No. 6,209,632. U.S. patent application Ser. No. 08/981,070 was the National Stage of International Application No. PCT/CA96/00407, filed Jun. 11, 1996. International Application No. PCT/CA96/00407 claims benefit of Canadian Patent Application Serial No. 2,151,525, filed on Jun. 12, 1995. 
     
    
     BACKGROUND OF THE INVENTION  
       [0003]     1. Field of the Invention  
         [0004]     This invention generally relates to borehole telemetry. More particularly, the invention relates to an electrically insulating gap sub assembly used for electromagnetic telemetry between surface and subsurface locations or between multiple subsurface locations.  
         [0005]     2. Description of the Related Art  
         [0006]     During a typical drilling operation, a wellbore is formed by rotating a drill bit attached at an end of a drill string. To provide for a more efficient drilling operation, various techniques may be employed to evaluate subsurface formations, such as telemetry, as the wellbore is formed. Generally, telemetry is a system for converting the measurements recorded by a wireline or measurements-while-drilling (MWD) tool into a suitable form for transmission to the surface. In the case of wireline logging, the measurements are converted into electronic pulses or analog signals that are sent up the cable. In the case of MWD, they are usually converted into an amplitude or frequency-modulated pattern of mud pulses. Some MWD tools use wirelines run inside the drill pipe. Others use wireless telemetry in which signals are sent as electromagnetic waves through the Earth. Wireless telemetry is also used downhole to send signals from one part of a MWD tool to another. The most commonly used drilling telemetry methods can be arranged into several distinct groups such as wireline, mud pulse, or electromagnetic (EM).  
         [0007]     In the first telemetry group, wireline communication involves one or more insulated cables that has a wide bandwidth and thus can communicate large amounts of data quickly, but the cable must be pulled out of the hole when adding additional sections of drill pipe. This is time consuming and reduces overall drilling efficiency. It also may not be possible to rotate the drill string with the wireline cable in the hole.  
         [0008]     In the second telemetry group, mud pulse telemetry, the drilling fluid is utilized as the transmission medium. As the drilling fluid is circulated in the wellbore, the flow of the drilling fluid is repeatedly interrupted to generate a varying pressure wave in the drilling fluid as a function of the downhole measured data. A drawback of the mud pulse technique is that the data transmission rates are very slow. Transmission rates are limited by poor pulse resolution as pressure pulses attenuate along the borehole and by the velocity of sound within the drilling mud. Further, while mud pulse systems work well with incompressible drilling fluids such as a water-based or an oil-based mud, mud pulse systems do not work well with gasified fluids or gases typically used in underbalanced drilling.  
         [0009]     In the third telemetry group, electromagnetic (EM) telemetry, relatively low frequency (4-12 Hz) electromagnetic waves are transmitted through the earth to the surface where the signal is amplified, filtered, and decoded. Communication may also be accomplished in the reverse direction.  
         [0010]     In a typical EM operation, generating and receiving the electromagnetic waves downhole involves creating an electrical break between an upper section and a lower section of a drill string to form a large antenna. Thereafter, sections of this antenna are energized with opposite electrical polarity often using a modulated carrier wave that contains digital information. The resulting EM wave travels through the earth to the surface where a potential difference may be measured between a rig structure and a point on the surface of the earth at a predetermined distance away from the rig.  
         [0011]     Typically, the electrical break in the drill string is accomplished by a device referred to as a gap sub assembly. Generally, the gap sub assembly must electrically insulate the upper and lower sections of the drill string and yet be structurally capable of carrying high torsional, tensile, compressive, and bending loads. The known gap sub assembly includes an external non-conductive section with composite coatings to isolate the upper and lower sections. However, these coatings generally lack sufficient abrasion resistance when in contact with the abrasive rock cuttings and require frequent maintenance or replacement. In addition, the composite coatings typically do not provide a significant beneficial effect to the bending or compressive strength of the design. Additionally, the known gap sub assembly is expensive to manufacture. Furthermore, the known gap sub assembly is bulky and cumbersome to employ during a drilling operation.  
         [0012]     Therefore, a need exists for a gap sub assembly that is capable of withstanding the abrasive environment of a wellbore. Further, there is a need for a gap sub assembly that is capable of withstanding the bending and compressive loading that occurs during a drilling operation. Furthermore, there is a need for a gap sub assembly that is cost effective to manufacture. Further yet, a need exists for a gap sub assembly that is compact and may be easily employed during a drilling operation.  
       SUMMARY OF THE INVENTION  
       [0013]     This invention overcomes the problem of creating an electrical break in the drill string in a compact and cost effective yet highly robust method.  
         [0014]     In one embodiment, an apparatus for use with an EM telemetry system is provided, comprising: a housing; a mandrel; a dielectric material disposed between the housing and the mandrel; and a first non-conductive gap ring disposed between the housing and the mandrel.  
         [0015]     Optionally, the mandrel is bonded to the housing with the dielectric material. The housing and the mandrel may be configured to remain axially coupled in the event of failure of the dielectric material. The housing and the mandrel section may be attached by a threaded connection so that the housing and the mandrel remain axially coupled in the event of failure of the dielectric material. The dielectric material may be disposed in the threaded connection. The apparatus may further comprise an anti-rotation member configured so that the housing and the mandrel remain rotationally coupled in the event of failure of the dielectric material. The anti-rotation member may comprise at least one non-conductive torque pin disposed between the housing and the mandrel. The first gap ring may be fabricated from a toughened ceramic material. The first gap ring may provide structural support in bending and compression. The first gap ring is may be preloaded in compression between the housing and the mandrel to provide a seal between the housing and the mandrel. The dielectric material may be epoxy.  
         [0016]     Further, the mandrel may comprise a first section and a second section coupled by a threaded connection. The housing may comprise a first section and a second section coupled by a threaded connection. The first gap ring may be disposed between the second section of the housing and the second section of the mandrel. The apparatus may further comprise a second non-conductive gap ring disposed between the first section of the housing and the first section of the mandrel. The apparatus may further comprise a first seal assembly disposed between the second section of the housing and the first section of the mandrel. The first seal assembly may comprise a first sleeve made from a relatively high strength, high temperature plastic; and at least one elastomer sealing element disposed between the first sleeve and the second section of the housing and at least one elastomer sealing element disposed between the first sleeve and the first section of the mandrel. The apparatus may further comprise a second seal assembly similar to that of the first seal assembly. The apparatus may further comprise: a first compression ring disposed between the first gap ring and the mandrel and a second compression ring disposed between the first gap ring and the housing. The compression rings may be made from a relatively soft, strain-hardenable material.  
         [0017]     In another embodiment, an apparatus for use with an EM telemetry system is provided, comprising: a housing; a mandrel; a dielectric material bonding the mandrel to the housing, wherein the apparatus is configured so that the housing and the mandrel remain coupled in the event of failure of the dielectric material.  
         [0018]     In another embodiment, an apparatus for use with an EM telemetry system, comprising: a housing; a mandrel; means for electrically isolating the housing from the mandrel and for primarily coupling the housing to the mandrel; and means for secondarily coupling the housing to the mandrel in the event of failure of the primary coupling means.  
         [0019]     In another embodiment, a method of receiving data from a wellbore, comprising: placing a gap sub assembly between an upper portion and a lower portion of a drill string, the gap sub assembly comprising: a housing; a mandrel; a dielectric material disposed between the housing and the mandrel; and a first non-conductive ring disposed between the housing and the mandrel; positioning the drill string and the gap sub assembly in the wellbore; energizing the upper portion and the lower portion of the drill string with opposite electrical polarity, thereby forming the electromagnetic wave; and measuring the electromagnetic wave at a predetermined point on the surface of the wellbore.  
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0020]     So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.  
         [0021]      FIG. 1  illustrates a drilling rig structure and an EM telemetry system utilizing a gap sub assembly of the present invention.  
         [0022]      FIG. 2  illustrates a cross-sectional view of the gap sub assembly.  
         [0023]      FIG. 2A  illustrates an expanded view of dielectric filed threads in the gap sub assembly.  
         [0024]      FIG. 2B  illustrates an expanded view of an external gap ring disposed in the gap sub assembly.  
         [0025]      FIG. 3  illustrates a cross-sectional view of the gap sub assembly.  
         [0026]      FIG. 3A  illustrates an expanded view of a non-conductive seal arrangement in the gap sub assembly.  
         [0027]      FIG. 3B  illustrates an expanded view of a plurality of torsion pins in the gap sub assembly.  
         [0028]      FIG. 4  illustrates an expanded view of an alternative embodiment of the gap sub assembly. 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0029]     Embodiments of the present invention generally provide a method and an apparatus for use in an EM telemetry system. For ease of explanation, the invention will be described generally in relation to drilling directional wells, but it should be understood, however, that the method and the apparatus are equally applicable in other telemetry applications. Furthermore, it should be noted that the principles of the present invention are applicable not only during drilling, but throughout the life of a wellbore such as logging, testing, completing, and producing the well.  
         [0030]      FIG. 1  illustrates a drilling rig structure  40  and an EM telemetry system  100  utilizing a gap sub assembly  15  of the present invention. Generally, the EM telemetry system  100  may be used as a method to generate and receive the electromagnetic waves downhole. The method typically involves creating an electrical break between an upper section  10  and a lower section  20  of a drill string  60  to form a large antenna. The sections  10 ,  20  of this antenna are energized with opposite electrical polarity, often using a modulated carrier wave that contains digital information which results in an EM wave  30 . Thereafter, the EM wave  30  travels through the earth to the surface where a potential difference may be measured between the rig structure  40  and a point  50  on the surface of the earth at a predetermined distance away from the rig.  
         [0031]     In the embodiment illustrated, the electrical break in the drill string  60  is accomplished by a device referred to as the gap sub assembly  15 . Generally, the gap sub assembly  15  is an electrical isolation joint disposed between the upper and lower sections  10 ,  20  of the drill string  60 . Preferably, the gap sub assembly  15  is constructed and arranged to carry high torsional, tensile, compressive, and bending loads.  
         [0032]     It has been determined that the transmission efficiency of EM telemetry system  100  can be improved by increasing the non-conductive length of the gap on the exterior and interior in the range of 2-3″ or more, compared with a very small gap, in the range of 1/32″. The improvement is especially pronounced when the gap sub assembly  15  is immersed in conductive drilling fluids, as is often the case. The reason for this is that as the gap length is increased, the electrical resistance of the fluid path between the sections  10 ,  20  increases, and more of the current flows through the formation and thus to the surface instead of through the fluid where it does not provide any transmission benefit.  
         [0033]      FIG. 2  illustrates a cross-sectional view of the gap sub assembly  15 . As shown, the gap sub assembly  15  consists of a lower threaded member  101  which mates with a lower portion of the drill string (not shown) and an upper threaded member  102  which mates with an upper portion of the drill string. Alternatively, the gap sub assembly may be disposed in the drill string upside down. Disposed between the upper and lower threaded members  101 ,  102  is a mandrel  104 , a housing  103 , and a first gap ring  105 .  
         [0034]     The upper threaded member  102  and lower threaded member  101  serve as thread savers for the housing  103  and mandrel  104 . For instance under normal operating conditions, the upper threaded member  102  and lower threaded member  101  remain torqued up to the housing  103  and mandrel  104  respectively. Thereafter, exposed threads  113  and  114  are then used to attach the drill string above and below the gap sub assembly  15 . The sequence of mating and unmating of these threads is done frequently and causes wear which may require re-cutting the threads. Eventually when the upper threaded member  102  and the lower threaded member  101  become too short to further re-cut, they may easily be replaced without requiring the entire gap sub assembly  15  to be replaced. Alternatively, the housing  103  and the upper threaded member  102  may be formed as one-piece and the mandrel  104  and the lower threaded member  101  may also be formed as one-piece.  
         [0035]      FIG. 2A  illustrates an expanded view of dielectric filed threads  107  in the gap sub assembly  15 . As shown, the mandrel  104  contains an external threadform that has a larger than normal space  108  between adjacent threads. In the same manner, the housing  103  has an internal threadform with widely spaced threads  107 . The mandrel  104  and housing  103  are separated from each other by a dielectric material  109 , such as epoxy, which is capable of carrying axial and bending loads through the compression between adjacent threads. Typically, the load carrying ability of most dielectric materials is much higher in compression than tension and/or shear. In this respect, the total surface area bonded with the dielectric material  109  may also be increased dramatically over a purely cylindrical interface of the same length. Therefore, the increased surface area equates to higher strength in all loading scenarios.  
         [0036]     Additionally, if the dielectric material  109  adhesive bonds fail and/or the dielectric material  109  can no longer carry adequate compressive loads due to excessive temperature or fluid invasion, the metal on metal engagement of the threads  107  prevents the gap sub assembly  15  from physically separating. Therefore, the mandrel  104  will remain axially coupled to the housing  103  and may be successfully retrieved from the wellbore.  
         [0037]      FIG. 2B  illustrates an expanded view of the first gap ring  105  disposed in the gap sub assembly  15 . In the preferred embodiment, the first gap ring  105  is constructed from a toughened ceramic material, such as yttria stabilized tetragonal zirconia polycrystals, as it is a highly abrasion resistant, as well as an impact resistant material. Zirconia also has an elastic modulus and thermal expansion co-efficient comparable to that of steel and an extremely high compressive strength (i.e. 290 ksi) in excess of the surrounding metal components. These properties allow the first gap ring  105  to support the joint under bending and compressive loading producing a significantly stronger and robust gap sub assembly  15 . One advantage of a first gap ring  105  over that of a coated annular disc is that coatings may become scratched revealing the conductive underlying material. Another advantage of the first gap ring  105  is that a non-porous surface is easily achieved, whereas suitable high temperature coatings, such as flame deposited ceramic are highly porous preventing their use generally as a reliable sealing surface.  
         [0038]     In the preferred embodiment, a primary external seal  110  is formed by torquing the lower threaded member  101  onto the mandrel  104  to compress the first gap ring  105  between the two halves of the gap sub assembly  15 , thereby forming the primary external seal  110  on the faces of the first gap ring  105 . The combination of high compressive stress, good surface finish, and low porosity in the first gap ring  105  produces a high pressure, high temperature seal that is compatible with the entire range of drilling fluids. In addition to the stress required between faces to seal under no-load conditions, a higher compressive stress is required to maintain face to face contact during bending and/or tension.  
         [0039]     In an alternative embodiment, the primary external seal  110  may be formed by mechanically stretching the mandrel  104  by the use of a hydraulic cylinder (not shown) or other device. Thereafter, as the mandrel  104  is maintained in the stretched condition, the lower threaded member  101  can be threadingly advanced until it is in contact with the external gap ring  105 , even though no significant torque has been applied. Upon releasing the stretch on the mandrel  104 , the high compressive forces on the faces of the first gap ring  105  forms the primary external seal  110 . In another alternative embodiment, the primary external seal  110  may be formed by cryogenically cooling the first gap ring  105  and subsequently mating the lower threaded member  101  thereto. As the first gap ring  105  warms up, it will expand creating the desired compressive forces to form the primary external seal  110 .  
         [0040]     The use of the first gap ring  105  in the gap sub assembly  15  of the present invention may provide several advantages. A first advantage is that it forms a structural element supporting the gap sub assembly  15  in bending and compression. A second advantage is that it provides a significant non-conductive external length which is virtually impervious to abrasion. A third advantage is that the first gap ring  105  is the primary external seal compatible with the full chemical and temperature range of drilling fluids.  
         [0041]     As further shown on  FIG. 2B , a secondary seal arrangement is disposed adjacent the external gap ring  105 . The secondary seal arrangement includes a first sleeve  106  made from a high strength, high temperature plastic, such as PEEK and a series of elastomer seals  112 ,  111  disposed on the interior of the housing  103  and the exterior of the mandrel  104 , respectfully. Preferably, the seals  112 ,  111  prevent fluid from entering the space between the mandrel  104  and the housing  103  if the primary seal  110  should fail. Furthermore, the first sleeve  106  supports the first gap ring  105  and provides some shock absorption should the first gap ring  105  experience a severe lateral impact. In another aspect, the ability to remove the lower threaded member  101  easily allows the seals  112 ,  111  and the first sleeve  106  to be inspected and replaced during a regular maintenance program.  
         [0042]      FIG. 3  illustrates a cross-sectional view of the gap sub assembly  15 .  FIG. 3A  illustrates an expanded view of an internal, non-conductive seal arrangement  160  in the gap sub assembly  15 . Preferably, the internal, non-conductive seal arrangement  160  includes a second sleeve  151  formed from a high temperature, high strength dielectric material, such as PEEK, and a series of elastomer seals  155 ,  156  disposed on the mandrel  104  and housing  103  respectively. Preferably, the elastomer seals  155 ,  156  prevent drilling fluid from entering the internal space between mandrel  104  and housing  103 .  
         [0043]     As further shown in  FIG. 3A , a second, non-conductive gap ring  157  is provided in the bore of the gap sub assembly  15  to improve the electrical performance of the system. More specifically, as with the first gap ring  105 , the second, non-conductive gap ring  157  increases the path length that the current must flow through, thereby increasing the resistance of that path, and thus decreasing the unwanted current flow in the interior of the gap sub assembly  15 . In this manner, more of the current flows through the formation and thus to surface, instead of through the fluid where it does not provide any transmission benefit. Preferably, the second gap ring  157  is formed from a high temperature, high strength dielectric material, such as PEEK.  
         [0044]      FIG. 3B  illustrates an expanded view of the plurality of non conductive torsion pins  150  in the gap sub assembly  15 . The torsion pins  150  are constructed and arranged to ensure that no relative rotation between the mandrel  104  and housing  103  may occur, even if the dielectric material  109  bond fails. In the preferred embodiment, the torsion pins  150  are cylindrical pins disposed in matching machined grooves  154  and  153 . It is to be understood, however, that other forms of non-conductive devices may be employed such as non-conductive material forming keys in surrounding keyways, splines separated by a plastic insert, hexagonal sections separated by a non-conductive material, or a variety of other means known in the art to prevent rotation.  
         [0045]      FIG. 4  illustrates an expanded view of an alternative embodiment  215  of the gap sub assembly  15 . Only a portion of the alternative gap sub assembly  215  is shown because the rest of the alternative gap sub assembly is identical to the gap sub assembly  15 . Parts that have not been substantially modified in this embodiment have retained the same reference numerals as that of gap sub assembly  15 . In this embodiment, a first compression ring  205 A is disposed between the housing  103  and the first gap ring  105 . Since the first compression ring  205 A radially extends to the mandrel  104 , the first sleeve  106  has been split into two pieces  206 A,B. A second compression ring  205 B is disposed between the first gap ring  105  and the lower threaded member  101 . Preferably, the compression rings  205 A,B are made from a relatively soft strain hardenable material, such as an aluminum and bronze alloy.  
         [0046]     During testing of an embodiment of the gap sub assembly  15 , it was observed that when the preload was removed from the first gap ring  105  cracking resulted in the first gap ring  105 . Since the cracks did not form until the preload was removed, operation of the first gap ring  105  is unaffected. However, the cracks would necessitate replacement of the gap ring  105  possibly every time the gap sub assembly  15  is dismantled. This is undesirable from a cost perspective since the preferred zirconia material is relatively expensive. It is believed that the cracking stems from surface imperfections in ends of the housing  103  and the lower threaded member  101  facing respective ends of the first gap ring  105 . The relatively rough surface finish causes point loading between the first gap ring  105  and the housing  103  and lower threaded member  101 .  
         [0047]     To mitigate the point loading effect, each end of the housing  103  and the member  101  facing the first gap ring  105  would have to be machined to a relatively fine surface finish. Machining the required surface finish would be time consuming and expensive. However, addition of the compression rings  205 A,B also mitigates the point loading effect. The preferred relatively soft material of the rings  205 A,B conforms to the surface imperfections in the first gap ring  105  as the connection is torqued, thereby distributing the load over the entire respective surfaces of the first gap ring. The compression rings  205 A,B will also preferably strain harden during torquing of the connection, thereby obtaining effects of increased strength and hardness which are beneficial to the service life of the compression rings. Therefore, compression rings  205 A,B provide a simple and inexpensive fix to the cracking problem. Further, it is believed that the compression rings  205 A,B may also minimize any torsional stress sustained by the first gap ring  105 .  
         [0048]     While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.

Technology Classification (CPC): 4