Abstract:
A downhole casing guide member comprising a structure having a unitary formation wherein in a plane perpendicular to a center longitudinal axis of the structure, the unitary formation is generally &#34;Y&#34; shaped in two opposite directions about the center longitudinal axis. The downhole casing guide member further comprises at least one clamping bracket member securable to the structure. The unitary formation of the structure serves to maximize available flow area for flow of fluid, liquid slurry and/or cement around the contour of the unitary formation and maximize the diameters of casing strings which may be run within a conductor casing; and tapered upper and lower shoulders on the casing guide member ease passage of the guide member into and out of a conductor casing. Further, the overall configuration and shape of the downhole guide member eases passage of casing strings lowered into or removed from the conduits formed by the guide member.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to downhole guide members employed in subterranean boreholes, typically drilled for oil and gas wells. More particularly, the invention relates to a downhole casing guide member comprising a uniquely contoured structure which guides multiple casing strings downhole and maintains such multiple casing strings in substantially fixed, side-by-side relationship with one another downhole within a conductor casing. The contour of the structure maximizes available cross sectional fluid flow area in a conductor casing, in a plane perpendicular to the center longitudinal axis of the conductor casing, to minimize fluid pressure losses when flowing fluids such as drilling fluids or cement slurries around the structure. Moreover, the contour of such structure, in the plane perpendicular to the longitudinal axis of the conductor casing, maximizes the diameter of the casing strings which may be run within a given conductor casing diameter by forming two bores, spaced substantially 180° apart, where a portion of each bore is formed by a portion of the inner wall of the conductor casing. Additionally, the contour of the structure presents tapered upper and lower shoulders which ease insertion into and removal from the conductor casing. 
     2. General Background 
     In the development of certain oil and gas fields, it is at times highly desirable to drill multiple, directionally drilled wellbores from a common surface location inside a single large &#34;conductor casing&#34; string. This is especially so in certain offshore oil and gas developments. In the following description, the term &#34;conductor casing&#34; refers generally to the initial, generally large diameter casing string installed, through which multiple wells may be drilled. Conductor casing is typically driven, drilled, or jetted into place so that the lowermost end (the &#34;shoe&#34;) is several hundred feet below the mudline. 
     After the conductor casing is in place, individual wellbores are drilled and the initial casing string of each individual well is run and cemented in place. In this description, the initial casing string for each individual well is referred to as &#34;surface casing &#34;. Although the process and present invention are described in terms of two surface casing strings run within a conductor casing, it is understood that the invention is not limited to arrangements comprising two surface casing strings and in fact comprises different numbers of surface casing strings. Typical arrangements employ two 13-3/8&#34; surface casing strings run substantially side-by-side within a 36&#34; conductor casing, although other combinations of conductor and surface casing diameters may be used and are within the scope of the present invention. 
     A typical sequence of operations is as follows: a 36&#34; conductor string is driven into the earth so that the casing shoe is several hundred feet below the mudline, or ocean floor. As water depths may be several hundred feet, the total length of conductor casing may be on the order of 1000&#39;. A large diameter drill bit, typically approaching the inner diameter of the conductor casing, is then used to drill out the conductor casing to a depth slightly beyond the conductor casing shoe. Thereafter, a sequence of installation of a downhole casing guide member in the conductor casing, drilling of surface casing holes, and running and cementing of two surface casing strings follows. The operations may vary depending upon the type of guide member used. Drilling, formation evaluation, running of additional casing strings, etc., in each borehole, then proceeds in generally conventional manner through each surface casing string. 
     It is important for the two surface casing strings to be held downhole in fixed, side-by-side spacing with respect to one another, and the downhole casing guide members serve this purpose. Fluid flow past the downhole casing guide members is necessary for passage of drilling fluids (commonly called &#34;mud&#34;) and cement slurries during the drilling of the surface holes and the running and cementing of the surface casing strings. It is desirable, then, that the downhole casing guide member retain the surface casing strings in fixed side-by-side position while permitting use of the largest possible surface casing strings within a given conductor casing, and while occupying as little as possible of the available cross sectional fluid flow area within the conductor casing, thereby preserving relatively uninhibited fluid flow past the guide member. Further, as the guide member must be run into (and at times retrieved from) the conductor casing, a profile which minimizes &#34;hanging up&#34; on ledges, obstructions and the like is desired. 
     One such structure is described in U.S. Pat. No. 5,560,435, to Sharp, entitled &#34;Method and Apparatus for Drilling Multiple Offshore Wells from Within a Single Conductor String.&#34; The invention, by Sharp, discloses a method of drilling multiple wells in a conductor casing string. The invention, by Sharp, uses a downhole drilling guide which is a cylindrical member having two opposing flat, planar surfaces, and includes multiple guide bores in a side-by-side, parallel alignment, for receiving a casing string in each guide bore. The guide member is installed by running it downhole on one surface casing string (secured on a releasable connector) until the guide member rests on an internal shoulder in the conductor casing. Surface casing strings are then run through the guide bores. The configuration of the guide member of Sharp results in little available flow area in the conductor casing when the guide member and surface casing strings are in place. Use of only a single guide member as taught by Sharp may make it difficult to properly guide the second surface casing string through the guide bore. In addition, the relatively abrupt shoulders of the Sharp apparatus would tend to &#34;hang up&#34; on ledges, obstructions and the like within the conductor casing string. 
     Another such structure is described in U.S. Pat. No. 5,458,199, to Collins et al., entitled &#34;Assembly and Process for Drilling and Completing Multiple Wells.&#34; The invention, by Collins et al., uses a downhole tie-back assembly to maintain the casing strings separated while downhole. The downhole tie-back assembly comprises bores for running the casing strings therethrough. In one embodiment, a first casing string is is threaded into screw threads in the first bore, and the first casing string is used to lower the tie-back assembly into place. A collet latch is attached to the exterior of the second casing string, and that collet latch snaps into a mating profile in the second bore, thus connecting the second casing string to the tie-back assembly. Relatively little flow area remains in the conductor casing with installation of the tie-back assembly and the two casing strings. Additionally, the maximum size of casing strings that may be run within the conductor casing is reduced due to the tie-back assembly bores completely encompassing the casing strings, and the relatively abrupt shoulders of the Collins et al assembly may result in hang-ups on interior ledges, etc. in the conductor casing during running. 
     As can be appreciated, the known downhole casing guide member structure and tie-back assemblies require at least one of the surface casing strings to be latched or secured to the downhole guide member and tie-back assembly to lower such downhole guide member downhole. In effect, one of the surface casing strings serves as the &#34;running string&#34; for the downhole guide member. Moreover, once both casing strings are installed in the downhole guide members of known design, the remaining fluid flow area around the downhole guide member and/or tie-back assembly and the first and second surface casing strings is insufficient for easy flow of displaced drilling fluids and/or cement slurries around the downhole guide member and/or tie-back assembly. Although the maximum diameter of casing strings that may be run within a conductor is (in the case of two casing strings) fundamentally limited to one-half of the inner diameter of the conductor, with the downhole casing guide members of known design the maximum outer diameter of the two casing strings is further limited by the bores in the downhole guide member being completely contained within the diameter of the downhole guide member. The abrupt upper and lower shoulders on the downhole guide members of known design do not permit easy passage past ledges or obstructions in the conductor casing. 
     SUMMARY OF THE PRESENT INVENTION 
     The preferred embodiment of the apparatus of the present invention solves the aforementioned problems in a straight forward and simple manner. In the preferred embodiment, the present invention comprises a downhole casing guide member comprising a uniquely contoured structure which: 
     guides two surface casing strings downhole and maintains such two surface casing strings in substantially fixed, side-by-side spaced relation in the conductor casing; 
     has a contour which maximizes the available fluid flow area, after installation of the downhole guide member and casing strings, in a plane perpendicular to the center axis of the conductor casing; 
     has a contour, in a plane perpendicular to the center axis of the conductor casing, which maximizes the outer diameter of the surface casing strings which may be run downhole within a given diameter of conductor casing, by forming two bores, spaced substantially 180° apart, wherein a portion of each bore is formed from a portion of the inner wall of the conductor casing; 
     is adapted to be run and deployed downhole in a conductor casing on at least one running string, independently from any casing string; and 
     has tapered upper and lower entry surfaces or shoulders which ease passage of the downhole guide member within the conductor casing. 
     The downhole casing guide member of the present invention comprises a structure having a center longitudinal axis substantially coincident with the center longitudinal axis of the conductor casing, wherein the formation of such structure in a plane perpendicular to such center axis is generally &#34;Y&#34; shaped in two opposite directions about the center longitudinal axis of the structure. In other words, the formation of such structure in a plane perpendicular to such center longitudinal axis is generally &#34;Y&#34; shaped in a first direction and generally &#34;Y&#34; shaped in a second direction offset 180° from said first direction. 
     In view of the above, it is an object of the present invention to provide a downhole casing guide member comprising a structure having a center spacing member elongated in the plane perpendicular to the longitudinal axis of the conductor casing; a first pair of radial leg support members wherein each radial leg support member of the first pair flares radially angularly in different directions from one end of the elongated center spacing member; and a second pair of radial leg support members wherein each radial leg support member of the second pair flares radially angularly in different directions from the other end of the elongated center spacing member. The gaps between the two radial leg support members of the first and second pairs form first and second passages, respectively, for fluid flow therethrough. 
     Another object of the present invention is to provide a structure with first and second cavities which have axes parallel to the center longitudinal axis of the conductor casing. The first and second cavities extend into the first and second passages, respectively, for passage therethrough of first and second tubular members or &#34;running strings&#34; wherein the tubular members are clamped in their respective cavities with respective clamping bracket members. At least one of the first and second tubular members is required to lower the downhole casing guide member downhole in the conductor casing to a predetermined depth. 
     A further object of the present invention is to provide such a downhole casing guide member which is capable of being lowered downhole via at least one tubular member running string clamped thereto. Therefore the use of the surface casing string for lowering the downhole casing guide member is eliminated and the surface casing string need not be secured to the downhole casing guide member. 
     It is a still further object of the present invention to provide the uniquely contoured structure with two trough-shaped conduits, each spaced substantially 180° apart, thereby forming two bores for guiding in each bore a respective casing string downhole and maintaining each such respective casing string in substantially fixed spaced relation with respect to the other downhole in the conductor casing. One of the trough-shaped conduits is formed by a first concaved surface connecting the distal end of the first radial leg support member of the first pair and the distal end of the first radial leg support member of the second pair. The other trough-shaped conduit is formed by a second concaved surface connecting the distal end of the second radial leg support member of the first pair and the distal end of the second radial leg support member of the second pair. The first bore, for guiding therein a first surface casing string, is defined by the trough-shaped conduit and the curvature of the interior surface of the conductor casing between the first radial leg support member of the first pair and the first radial leg support member of the second pair. The second bore, for guiding therein a second surface casing string, is defined by the trough-shaped conduit and the interior surface of the conductor casing between the second radial leg support member of the first pair and the second radial leg support member of the second pair. 
     It is a still further object of the present invention to provide two bores which have a distorted circular outline to provide passageways on each side of a surface casing string when run in its respective bore wherein such passageways allow drilling fluids and/or cement slurries to flow along the side of the surface casing strings within the bore of the conductor casing. 
     It is a still further object of the present invention to provide such a downhole casing guide member which allows the diameter of the two surface casing strings which may be run within a conductor casing to be maximized. 
     It is a further object of the present invention to provide a downhole casing guide member which has a top surface and a bottom surface parallel to the top surface wherein the top surface and the bottom surface have beveled ends in close proximity to the outer perimeter thereof, for enhancing passage of the downhole casing guide member into and out of the conductor casing. More specifically, at least a portion of the top and bottom surfaces of each of the radial leg support members of the first and second pairs are beveled. 
     In view of the above objects it is a feature of the present invention to provide a downhole casing guide member which generally includes a uniquely contoured unitary structure and two clamping support bracket members capable of being secured to such structure. 
     It is another feature of the present invention to provide a downhole casing guide member which is structurally relatively simple. 
     It is a further feature of the present invention to provide a downhole casing guide member which is relatively inexpensive to manufacture, and which may be formed in a unitary design, such as by casting or molding. 
     The above and other objects and features of the present invention will become apparent from the drawings, the description given herein, and the appended claims. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     For a further understanding of the nature and objects of the present invention, reference should be had to the following description in conjunction with the accompanying drawings in which like parts are given like reference numerals: 
     FIG. 1 is a perspective view of the downhole casing guide member of the present invention; 
     FIG. 2 is a top view of the downhole casing guide member of the present invention; 
     FIG. 3 is a top view of the downhole casing guide member installed in a conductor casing and having the first and second casing strings received within the two bores and the two tubular members clamped to the downhole casing guide member; 
     FIG. 4 is a sectional view along the plane of 4--4 of FIG. 31 
     FIG. 5 is a sectional view along the plane of 5--5 of FIG. 3; 
     FIG. 6 is a sectional view of FIG. 4, with running strings in place; 
     FIG. 7 is a sectional view of FIG. 5, with running strings in place; and 
     FIG. 8 is a perspective view of a plurality of downhole casing guide members of the present invention, being run into a conductor casing for placement therein. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring now to the drawings, and in particular FIGS. 1-7, the downhole casing guide member of the present invention is designated generally by the numeral 10. Certain of the drawings omit certain of the reference numerals for clarity. Downhole casing guide member 10 is generally comprised of structure 20 and first and second clamping bracket members 50a and 50b. 
     Structure 20 has a unitary formation bounded by the inner diameter of conductor casing 5. The unitary formation should provide for a sufficient annular clearance to allow downhole casing guide member 10 to fit within the inner diameter of conductor casing 5 and be lowered to a desired depth in conductor casing 5, as will be herein described. In the exemplary embodiment, downhole casing guide member 10 is bounded radially by radius R1, and is lowered in conductor casing 5 which has an inner radius slightly greater than radius R1. Downhole casing guide member 10 may be dimensioned to fit in any size conductor casing 5. 
     Structure 20 has center longitudinal axis 8 parallel to the center longitudinal axis of conductor casing 5. The unitary formation of structure 20 in a plane perpendicular to center axis 8 is generally &#34;Y&#34; shaped in two opposite directions about center longitudinal axis 8. In other words, the unitary formation of structure 20 in a plane perpendicular to center longitudinal axis 8 is generally &#34;Y&#34; shaped in a first direction and generally &#34;Y&#34; shaped in a second direction, where the second direction is offset 180° from the first direction. With downhole casing guide member 10 in place in conductor casing 5, the interior area of conductor casing 5 is substantially divided into two halves. 
     As can be readily seen, the unitary formation of structure 20 significantly reduces the cross sectional area of structure 20 occupying the interior of conductor casing 5, thereby maximizing the diameter of casing strings 7a and 7b (which may be surface casing strings) which can be run inside a given diameter of conductor casing 5. Moreover, the gap between the legs of each &#34;Y&#34; provides a passage for the flow of fluids, such as drilling fluids and/or cement slurries, therethrough. 
     More specifically, the unitary formation of structure 20 is defined by elongated center spacing member 23 which is elongated in a plane perpendicular to the center longitudinal axis of conductor casing 5; a first pair of radial leg support members 21a and 21b wherein each radial leg support member flares radially angularly in different directions from one end of elongated center spacing member 23; and a second pair of radial leg support members 22a and 22b wherein each radial leg support member flares radially angularly in different directions from the other end of elongated center spacing member 23. 
     The first pair of radial leg support members 21a and 21b and the second pair of radial leg support members 22a and 22b serve to center and support elongated center spacing member 23 within conductor casing 5, and additionally serve to section the interior of conductor casing 5. The gap between radial leg support member 21a and radial leg support member 21b of the first pair forms first passage 40a. Similarly, the gap between radial leg support member 22a and radial leg support member 22b of the second pair forms second passage 40b. First passage 40a and second passage 40b permit fluids, such as drilling fluids and/or cement slurries, to flow therethrough. 
     Structure 20 has first and second concaved surfaces 25a and 25b, is circumferentially spaced 180° apart, wherein such concaved surfaces 25a and 25b are substantially symmetrical about curvature mid points P1 and P2 and are bounded by circumference C. First and second concaved surfaces 25a and 25b form elongated center spacing member 23; in addition, first concaved surface 25a forms the exterior surfaces of radial leg support members 21a and 22a, and second concaved surface 25b forms the exterior surfaces of radial leg support members 21b and 22b. 
     First and second concaved surfaces 25a and 25b form first and second conduits 30a and 30b, respectively, which are trough-shaped and separated by elongated center spacing member 23. Elongated center spacing member 23 serves to space casing strings 7a and 7b within conductor casing 5. The distance from curvature mid point P1 of first concaved surface 25a, to point P1&#39; on circumference C, is diameter D1. Likewise, the distance from curvature mid point P2 of second concaved surface 25b, to point P2&#39; on circumference C, is diameter D2. Point P1&#39; is essentially the mid point of that section of circumference C between radial leg support members 21 a and 22a. Point P2&#39; is essentially the mid point of that section of circumference C between radial leg support members 21b and 22b. 
     With downhole casing guide member 10 in place within a conductor casing string, trough-shaped conduit 30a and the interior surface of conductor casing 5 between radial leg support members 21a and 22a form a first bore for guiding therethrough casing string 7a. Likewise, trough-shaped conduit 30b and the interior surface of conductor casing 5 between radial leg support members 21b and 22b form a second bore for guiding therethrough casing string 7b. 
     More specifically, trough-shaped conduits 30a and 30b defined by first and second concaved surfaces 25a and 25b, respectively, allow downhole casing guide member 10 to utilize the inner surface of conductor casing 5 to facilitate guiding casing strings 7a and 7b, respectively, downhole. Moreover, the use of the inner surface of conductor casing 5 allows the diameter of casing strings 7a and 7b to be maximized by eliminating any material or wall which would space casing strings 7a and 7b from the inner surface of conductor casing 5. 
     As can be appreciated, said first bore, having a portion thereof bounded by the interior surface of conductor casing 5, is capable of guiding therethrough casing string 7a wherein casing string 7a may have an outer diameter of slightly less than D1 or less to permit annular clearance of first casing string 7a within said first bore. Likewise, said second bore, having a portion thereof bounded by the interior surface of conductor casing 5, is capable of guiding therethrough casing string 7b wherein casing string 7b may have an outer diameter of slightly less than D2 or less to permit annular clearance of second casing string 7b. In the preferred embodiment, diameter D1 and D2 are equal. 
     As can be readily seen, said first bore and said second bore have distorted circular profiles in a plane perpendicular to the center axis of conductor casing 5. When first and second casing strings 7a and 7b are run through their respective bores, a gap exists on each side of first casing string 7a and on each side of second casing string 7b. Thereby, the contour of first concaved surface 25a provides first and second passageways 31a and 31a&#39; when first casing string 7a is journalled in said first bore for permitting fluid (such as, without limitation, drilling fluids and cement slurries) flow therethrough. Likewise, the contour of second concaved surface 25b provides first and second passageways 31b and 31b&#39; when second casing string 7b is run through said second bore for permitting fluid flow therethrough. 
     While said first bore and said second bore each have a distorted circular profile, the profiles do not compromise the necessary annular clearance for running therethrough first and second casing strings 7a and 7b, respectively. Moreover, the distorted circular profile of said first bore and said second bore provides a sufficient annular clearance which does not allow first casing string 7a and second casing string 7b, respectively, to roll side-to-side by any significant amount therein, when first and second casing strings 7a and 7b are maximized to D1 and D2, respectively, while providing passageways for the flow of drilling fluids and/or cement slurries. 
     The contour of first and second concaved surfaces 25a and 25b form first wedged shaped region A on one end of elongated center spacing member 23 and second wedged shaped region B on the other end of elongated center spacing member 23 wherein midpoints P3 and P4 of the arc defined by first and second wedged shaped regions A and B, respectively, are circumferentially spaced 180° apart. Structure 20 is not solid in first and second wedge shaped regions A and B. Instead, first and second wedged shaped regions A and B have formed therein first and second passages 40a and 40b, respectively. Since wedged shaped regions A and B are identical only one such wedged shaped region will be described in detail. 
     In the preferred embodiment, first passage 40a is generally trapezodially-shaped. Nevertheless, any geometrical shape may be substituted provided fluid flow is not significantly compromised. Trapezodially-shaped first passage 40a, formed in wedge shaped region A is defined by first and second linearly sloping surface walls 41a and 41b and surface wall 42. First and second linearly sloping surface walls 41a and 41b slope inwardly from circumference C to surface wall 42. 
     First and second linearly sloping surface walls 41a and 41b complete the contour of the first pair of radial leg support members 21a and 21b which radially project angularly in different directions from elongated center spacing member 23 and are bounded by circumference C. In other words, the exterior side surface wall of the first pair of radial leg support members 21a and 21b is curved and the interior side surface wall is linearly sloped. 
     In the preferred embodiment, top surface 47 and the bottom surface 47&#39; of radial leg support members 21a, 21b, 22a, and 22b of structure 20 are beveled to the distal ends thereof, forming shoulders 60, to facilitate the upward and downward movement of downhole casing guide member 10 downhole in conductor casing 5. 
     Each end portion 23a and 23b of elongated center spacing member 23 is flared as a result of the curvature of first and second concaved surfaces 25a and 25b. End portion 23a of elongated center spacing member 23 has formed therein arch-shaped cavity 27a. Arch-shaped cavity 27a may be semicircular or any other desirable arch shape. Similarly, end portion 23b of elongated center spacing member 23 has formed therein arch-shaped cavity 27b, which may be semicircular or any other desirable arch shape. 
     Since first and second clamping bracket members 50a and 50b are identical, only one will be described in detail. First clamping bracket member 50a comprises longitudinal support bar member 51a and first and second transverse bars 52a and 53a. Longitudinal support bar member 51a is longitudinally aligned substantially parallel to the center axis of conductor casing 5, thereby presenting minimal obstruction to fluid flow thereby. One end of longitudinal support bar member 51a has first transverse bar 52a coupled thereto, while the other end of longitudinal support bar member 51 a has second transverse bar 53a coupled thereto. Means for fastening first clamping bracket member 50a to structure 20 are provided, to fasten first clamping bracket member 50a to structure 20 with longitudinal support bar member 51a aligned substantially parallel to the center axis of structure 20 (and also of conductor casing 5, as described above). In the preferred embodiment, the means for fastening first clamping bracket member 50a to structure 20 comprises a plurality of threaded bolts 45 engaging threaded holes 45a in structure 20, with nuts 45c made up on bolts 45 and holding first clamping bracket member 50a securely to structure 20. Other fastening means well known in the art may also be used. In the preferred embodiment, first clamping bracket member 50a is formed from a integral construction of longitudinal support bar member 51a and first and second transverse bars 52a and 53a of metal alloys, by casting or forging. However, it is understood that first clamping bracket member and first and second transverse bars 52a and 53a may also be made of separate pieces joined by welding or other suitable means. 
     First and second transverse bars 52a and 53b, as may be clearly seen in FIGS. 1, 2, and 3, comprise a generally half-circle cutout 70 which is disposed substantially opposite cavity 27a in structure 20. Together, cutout 70 and cavity 27a comprise a circular area when first clamping bracket member 50a is attached to structure 20, providing a location for placing a tubular member 9a in said circular area and clamping structure 20 to tubular member 9a, as will be later described. 
     Second clamping bracket member 50b is of like construction to 50a. First and second transverse bars 52b and 53b, as may be seen in FIG. 4, comprise a generally half-circle cutout 80 which is disposed substantially opposite cavity 27b in structure 20. Together, cutout 80 and cavity 27b comprise a circular area when second clamping bracket member 50b is attached to structure 20, providing a location for placing a tubular member 9b in said circular area and clamping structure 20 to tubular member 9b, as will be later described. As described above, second clamping bracket member 50b is attached to structure 20 by bolts or other like means, well known in the art. 
     In the preferred embodiment, longitudinal support bar members 51a and 51b are an elongated arch-shaped in profile, bringing the outer extremities of longitudinal support bar members 51a and 51b substantially to circumference C. Thereby, longitudinal support bar members 51a and 51b provide added support for structure 20 by bearing against the inner wall of conductor casing 5. 
     Although many different materials and method of manufacture may be used to form structure 20 and clamping bracket members 50a and 50b, in one embodiment ductile iron is used. Furthermore, forming structure 20 in unitary fashion, such as by casting, produces a structure having high strength and minimum mass and consequently volume. However, it is understood that other materials may be used to form structure 20 and clamping bracket members 50a and 50b: other ferrous materials; non-ferrous materials, such as aluminum, zinc, and/or bronze alloys; and non-metallic materials such as plastics or fiber-reinforced composites. Other methods of manufacture of structure 20 and clamping bracket members 50a and 50b, depending upon material, could be molding, forging, welding together of sub-components, or other methods known in the art. 
     One method of use of the apparatus of the present invention is now described. With reference to FIGS. 6, 7, and 8, tubular member 9a, which may be casing, tubing or drill pipe having a diameter of approximately 5&#34; in an exemplary embodiment, is affixedly secured in arch-shaped cavity 27a via first and second transverse bars 52a and 53a of first clamping bracket member 50a. Tubular member 9b is affixedly secured in arch-shaped cavity 27b via first and second transverse bars 52b and 53b (only 53b shown) of second clamping bracket member 50b. The addition of arch-shaped cavities 27a and 27b for securing therein tubular members 9a and 9b provide a sufficient amount of unoccupied space in first and second passages 40a and 40b to allow fluids to flow through first and second passages 40a and 40b. While the preferred embodiment utilizes two tubular members to lower downhole casing guide member 10, it is understood that in alternative embodiments only one such tubular member may be used. 
     Thereafter, as illustrated in FIG. 8, a first (and ultimately deepest-set) downhole casing guide member 10 is lowered into conductor casing 5. Once a predetermined spacing has been reached, another downhole casing guide member 10 is clamped to first and second tubular members 9a and 9b. The assembly is then continued to be lowered into conductor casing 5, installing downhole casing guide members 10 at predetermined spacings, which in the exemplary embodiment may be every 100 to 150 feet, until the bottommost downhole casing guide member 10 is at a desired depth within conductor casing 5. For example, the lowermost downhole guide member 10 may be lowered to the seat (not shown) in the lower portion of primary conductor casing 5. Thus, in a 1000&#39; conductor casing, approximately ten downhole casing guide members 10 will be employed. First and second tubular members 9a and 9b may also serve to suspend downhole casing guide member 10 within primary conductor casing 5. 
     Next, a drilling assembly is lowered down one of the conduits thus formed in conductor casing 5, and a wellbore is drilled (having a diameter sufficient for the surface casing to be run) down to the desired surface casing setting depth. A first casing string 7a is then run to its setting depth and cemented in place. The second wellbore is then drilled in the remaining conduit, and a second casing string 7b is run and cemented in place. 
     A slightly different sequence of operations may also be followed. After the assembly of downhole guide members 10 is in place within conductor casing 5, when forming the first well of the multiple wells, first casing string 7a is lowered downhole to a depth sufficient to place first casing string 7a within the lowermost downhole casing guide member 10. Thereafter, a drillstring is run down first casing string 7a and drilling and/or under reaming is carried out to a desired casing running depth for first casing string 7a. The drillstring is removed, and first casing string 7a is lowered to said desired casing running depth and cemented in place. A similar process is carried out for second casing string 7b. Once casing strings 7a and 7b are cemented in place, drilling of the remainder of each well proceeds in generally conventional manner, well known in the art. 
     Because many varying and differing embodiments may be made within the scope of the inventive concept herein taught and because many modifications may be made in the embodiment herein detailed in accordance with the descriptive requirement of the law, it is to be understood that the details herein are to be interpreted as illustrative and not in a limiting sense.