Abstract:
A system and method for developing and recycling drilling fluids at the site of a subterranean well is described, thus eliminating the need for transporting the fluids to the site.

Description:
BACKGROUND  
         [0001]    This invention relates to a system and method of developing a drilling fluid in an efficient and environmentally-friendly manner. This invention further relates to recycling a drilling fluid.  
           [0002]    Drilling fluids are used downhole in well-drilling operations in treating subterranean wells. In offshore drilling operations, these drilling fluids are usually mixed onshore in large full scale production volumes and are delivered to the offshore platform by trucks and barges and stored for later use. However, this can be time-consuming, and the equipment needed to transport and store the drilling fluids is costly. Therefore what is needed is a system and method of developing drilling fluids which eliminates these problems. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0003]    [0003]FIG. 1 is a schematic view depicting an embodiment of the invention.  
         [0004]    [0004]FIG. 2 is a schematic view depicting an alternative embodiment of the invention. 
     
    
     DETAILED DESCRIPTION  
       [0005]    An embodiment of the system and method of the present invention will be described in connection with the drilling of a subterranean well in an offshore location with a water-based fluid in FIG. 1.  
         [0006]    Water, such as seawater, is recovered in any conventional manner and passes, via a conduit  10 , to a vessel  12  in which chemicals are added to the water to discourage bacteria growth. The treated water then passes through a conduit  14  under the action of a pump  16  and into a blender  20 .  
         [0007]    Specialty drilling additives from a container  22  are added to the water in the blender  20  to mix with the water to develop an initial water-based drilling fluid (hereinafter referred to as “drilling fluid”). The specialty drilling additives may include fluid controlling additives such as starches, encapsulating polymers, or other dry material such as caustic soda, sodium chloride, and silicic acid, and/or concentrated liqueurs.  
         [0008]    The drilling fluid then passes from the blender  20  through a conduit  24  under the action of a high shear pump  26 , which pumps the drilling fluid into a blender  30  and maximizes the efficiency of materials introduction. Various bulk materials, such as bentonite and barite, from a container  32 , mix with the drilling fluid in the blender  30  to further develop the drilling fluid. It will be understood that drilling additives and materials are drilling fluid components.  
         [0009]    The drilling fluid then passes from the blender  30  through a conduit  34  into an analyzer  36  which includes one or more of a number of specialty instruments such as a volume meter, a three-phase meter, a PH meter, and a mud analyzer for measuring rheology and other fluid properties. The analyzer  36 , including the above instruments, analyzes the drilling fluid and provides information as to the suitability of the drilling fluid for use downhole.  
         [0010]    If the analyzer  36  determines that the drilling fluid is suitable for use downhole, the drilling fluid from the analyzer is directed into a conduit  38  for passage to a downhole pump system  40 . If the analyzer  36  determines that the drilling fluid is unsuitable for use downhole, the drilling fluid is directed into a conduit  42  which is connected to the conduit  14  for recycling and therefore reconditioning the unsuitable drilling fluid.  
         [0011]    After entering and passing through the downhole pump system  40 , the drilling fluid passes through a conduit  44  to and through a hose system  50  and a kelly  51  to a downhole location for assisting in the further drilling of the well.  
         [0012]    After use, the drilling fluid is returned from the downhole location, via a conduit  52 , to a shale shaker  54  with vibrating screens to separate out larger drill cuttings (solids) for disposal. The drilling fluid then passes through a conduit  56  and into a degasser  58  to remove unwanted gas from the drilling fluid. For further cleaning, the drilling fluid then passes through a conduit  60  to a mud cleaner  62  that includes hydrocyclones positioned over small mesh screens to remove smaller drill cuttings for disposal.  
         [0013]    From the mud cleaner  62 , the majority of the drilling fluid is recycled through a conduit  64 . A smaller amount of drilling fluid passes through a conduit  66  to a centrifuge  68  wherein barite is separated out and recycled through a conduit  70 . The drilling fluid from the centrifuge  68  passes through a conduit  72  to another centrifuge  74  that separates out the smallest drill cuttings for disposal. The drilling fluid from the centrifuge  74  is then recycled through a conduit  76 . During the passage of the drilling fluid through the conduit  76 , the recycled barite from the conduit  70  and the drilling fluid from the conduit  64  are added and mixed with the drilling fluid in the conduit  76  to prepare the drilling fluid for entry into the analyzer  36 . The analyzer  36  again determines the suitability of the drilling fluid for reuse downhole. Alternatively, the recycled water-based drilling fluid may be passed, via the conduit  76 , to the sea or ocean in a safe manner adhering to environmental regulations or used to develop a new drilling fluid system for a new hole section.  
         [0014]    The separated drill cuttings from the shale shaker  54 , the mud cleaner  62 , and the second centrifuge  74  are extracted via conduits  80 ,  82 , and  84 , respectively, and sent back to shore for an environmentally safe disposal or disposed of on location if regulations allow.  
       Alternates and Equivalents  
       [0015]    [0015]FIG. 2 depicts an alternative embodiment of the system and method of the present invention that will be described in connection with the drilling of a subterranean well in an offshore location with a hydrocarbon-based fluid. The embodiment of FIG. 2 is similar to that of FIG. 1, and includes substantially similar components which are given the same reference numerals.  
         [0016]    A hydrocarbon-base fluid is delivered in any conventional manner to the conduit  10  for introduction into the vessel  12 . The hydrocarbon-base fluid is developed into a hydrocarbon-based drilling fluid (hereinafter referred to as “drilling fluid”) for use downhole in substantially the same manner as the water-based fluid in the previous embodiment. Thus, it passes through the system in the manner described above before it passes through the hose system  50  and the kelly  51  to a downhole location. The drilling fluid returns from the downhole location in a conventional manner and is passed through the shale shaker  54 , the mud cleaner  62  and the additional centrifuge  74  in the manner described above in connection with the embodiment of FIG. 1. Drill cuttings (solids) are removed from the shaker  54 , the mud cleaner  62  and the additional centrifuge  74  via conduits  80 ,  82 , and  84 , respectively and pass into a solvent extraction unit  86  to recover the hydrocarbon-base fluid.  
         [0017]    The solvent extraction unit  86  contains a lower pressure liquid recovery section, wherein the hydrocarbon-base fluid is recovered from the hydrocarbon-based drilling fluid still on the drill cuttings. In particular, the solvent extraction unit  86  contains lower boiling point hydrocarbon-based solvent fluids, or alternatively carbon dioxide, to extract the higher boiling point hydrocarbon-base fluid from the drill cuttings. The drill cuttings may then be disposed of in a safe manner adhering to environmental regulations through conduit  88 .  
         [0018]    After recovery of the hydrocarbon-base fluid, the solvent fluids undergo a recompression cycle so that they may be recycled for later use. The hydrocarbon-base fluid is then recycled to a storage container  92  via a conduit  94 . The storage container  92  stores the hydrocarbon-base fluid for reuse and is connected to the conduit  10  via a conduit  96  for recycling the hydrocarbon-base fluid back to the vessel  12  for reintroduction into the drilling fluid system.  
         [0019]    The benefits of this system are twofold. First, well construction costs can be reduced by minimizing the volume of drilling fluids used, maximizing the recycling of well-drilling fluids and cuttings, and reducing transportation costs associated with drilling fluids. Secondly, the drilling fluids and components of this system are environmentally friendly in that they are dramatically reduced in volume and can be reused for other well-drilling operations.  
         [0020]    Although only a few exemplary embodiments of this invention have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to cover the structures described herein as performing the recited function. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures.