Abstract:
A system for removing salt from a rich mono ethylene glycol (MEG) stream being fed into a flash separator isolates the fluid residing in the brine column of the separator from the MEG and introduces a swirling motive fluid into the column. The swirling motive fluid comes into contact with salt components residing in the isolated fluid of the column to create a salt slurry. The salt slurry is then removed and sent to a brine generation vessel. Saturated brine from the vessel is transported back to the column to replace the motive fluid in the column.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    This invention relates to processes designed to treat mono ethylene glycol (MEG) used in the oil and gas industry, especially in offshore locations, to control hydrates formation. More particularly, the invention relates to MEG reclamation processes which are designed to remove salts and other contaminants from a wet MEG feed stream. 
         [0002]    In the oil and gas industry, dry (lean) MEG is used to control the formation of hydrates within the produced stream. The now wet (rich) MEG is, in turn, dried by way of a MEG reclamation process so the MEG can be used again in hydrate control. The unit used to recover MEG usually includes three sections: pre-treatment, flash separation, and MEG regeneration. Those sections can be followed by salt management and calcium removal sections. 
         [0003]    In the pre-treatment stage, the rich MEG containing some dissolved gas and hydrocarbon liquids must pass through a three-phase separator vessel. The gas is flashed and recovered hydrocarbon liquids are sent to the production separator. The rich MEG is sent to a flash separator. The rich MEG stream comprised of produced water and MEG is fed to the flash separator where it is brought into contact with a hot recycle stream of MEG. The flash separator operates under vacuum. The MEG and water components of the rich MEG stream are flashed and exit through the top of the flash separator where they are sent to the MEG distillation column for regeneration. The salt components of the rich MEG stream precipitate in the flash separator. 
         [0004]    The MEG regeneration section is a refluxed distillation column. The distillation column also operates under vacuum and distills the water from the MEG-water vapors coming off the top of the flash separator. Salt-free, lean MEG produced at the bottom of the distillation column is pumped to storage for reuse. The vaporized water passes overhead from the distillation column. The water is condensed and collected in the reflux drum. A small amount is returned to the distillation column as reflux, and the remaining is routed to treatment. 
         [0005]    The salt crystals that precipitate in the flash separator are separated by gravity to the bottom of the brine column, where they are transferred to the salt tank. There, the salts are concentrated before removal through a centrifuge. 
         [0006]    The salts in produced water cover a variety of species, but generally are categorized into monovalent salts (typically sodium and potassium), and divalent salts (typically calcium and magnesium). The divalent salts cannot be effectively precipitated in the same manner as the monovalent salts, so a separate calcium removal process may be installed. Effective calcium control is accomplished as the divalent salts are collected, reacted and removed through a centrifuge with the centrate overflow returning to the process. 
         [0007]    Current methods of removing the salt crystals from bottom of the brine column involves a lot of equipment, including but not limited to complicated and expensive centrifugal filters or de-sanding cyclones, centrifuge pump filtration systems, a salt tank, a centrate tank, and a density measurement device. Reducing the footprint of the system required to remove the salt crystals is important for making more efficient use of space, reducing off-shore construction costs, and increasing ease of system operation and maintenance. 
       SUMMARY OF THE INVENTION 
       [0008]    A system for removing salt from a rich mono ethylene glycol (“MEG”) stream being fed into a flash separator includes means for isolating the fluid residing in the brine or downcomer column of the separator from the MEG, a solids fluidization device having means for causing a motive fluid to swirl when exiting the device; means for removing a salt slurry created by the swirling motive fluid. 
         [0009]    The isolating means is preferably an on-off valve located between a top and a bottom end of the brine column of the flash separator, the on-off valve when in the off position isolating the fluid residing in the brine column above the valve from the fluid residing and below the valve. A butterfly-type valve is an adequate on-off valve. 
         [0010]    The solids fluidization device is located within the brine column and below the on-off valve and has means that cause the motive fluid entering the device to swirl when exiting the device. The swirling motive fluid then comes into contact with salt components residing in the resident fluid isolated below the on-off valve. The motive fluid can be a produced water stream, a condensate water stream, or a stream that is some combination of the two. The swirling flow (e.g., vertiginous, rotary, or cyclonic) creates a salt slurry which is removed from the brine column by the removal means and passed to a brine generation vessel. 
         [0011]    The causing means is preferably a device having a plurality of slots located toward an upper end of the solids fluidization device and arranged tangential to, surrounding, and in communication with a central inner bore of the device. The removal means is preferably a slurry delivery head located in the brine column and directly above the solids fluidization device. 
         [0012]    The system further includes a brine generation vessel arranged to receive the salt slurry from the brine column. The brine generation vessel provides a saturated brine which can be transported back into the brine column and replace the motive fluid which was introduced earlier. 
         [0013]    A method of removing salt from a rich MEG stream being fed into a flash separator includes the steps of:
       i. isolating fluid containing solid/salt already residing toward a lower end of the brine column from MEG residing toward an upper end of the brine column;   ii. introducing a swirling motive fluid stream into a bottom end of the brine column to form a salt slurry stream; and   iii. removing the salt slurry stream.       
 
         [0017]    The isolating step is preferably done by way of an on-off valve, which could be a butterfly-type valve. The introducing step is preferably by way of a solids fluidization device having a plurality of spaced-apart vertical slots arranged tangential to, surrounding, and in communication with a central inner bore of the device. The removal step is by way of a slurry delivery head located above the solids fluidization device. After the step iii, a saturated brine stream can be introduced into the brine column as a way to displace the motive fluid. After the saturated brine stream is introduced into the column, the valve can be opened and the isolated fluids can be allowed to come into contact with one another again. 
         [0018]    The objectives of this invention are to (1) eliminate the need for complicated and expensive centrifugal filters and desanding hydrocyclones to remove salt; (2) eliminate the need for centrifuge filtration, a salt tank, a centrate tank, and density measurement devices; and (3) require less foot print than the prior art systems and methods and have lower construction costs and be easier to operate and maintain than those prior art systems and methods. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0019]      FIG. 1  is a schematic of a preferred embodiment of a salt transport system for a MEG reclamation or recovery process. The system includes a solids fluidization device located at the bottom end of the brine column of a flash separator and an on-off valve located between the fluidization device and the MEG/brine transition zone of the flash separator. 
           [0020]      FIG. 2  is a front elevation view of a preferred embodiment of the solids fluidization device of  FIG. 1 . 
           [0021]      FIG. 3  is top view of the solids fluidization device of  FIG. 2 . 
           [0022]      FIG. 4  is a cross-section view of the solids fluidization device of  FIG. 2 . 
           [0023]      FIG. 5  is a cross-section view of the solids fluidization device of  FIG. 2  taken along section line  5 - 5  of  FIG. 2 . 
           [0024]      FIG. 6  is an enlarged view of the solids fluidization device of  FIG. 1  and the removal device located directly above the solids fluidization device. 
       
    
    
     ELEMENTS AND NUMBERING USED IN THE DRAWINGS 
       [0025]      10  Salt transport system 
         [0026]      20  Flash separator 
         [0027]      21  Upper end 
         [0028]      25  Rich (wet) MEG stream 
         [0029]      27  Water and MEG vapor stream 
         [0030]      29  Brine or downcomer column or section 
         [0031]      31  MEG/brine transition zone 
         [0032]      33  On-off valve 
         [0033]      35  Recycle loop 
         [0034]      37  Bottom or lower end of  29   
         [0035]      39  Upper end of  29   
         [0036]      40  Sand removal device 
         [0037]      41  Inlet 
         [0038]      43  Upper end of  40   
         [0039]      45  Slots 
         [0040]      47  Inner bore 
         [0041]      49  Produced or condensate (carrier or motive) water stream 
         [0042]      51  Swirling motive fluid stream 
         [0043]      53  Salt slurry stream 
         [0044]      55  Removal device or slurry discharge head 
         [0045]      60  Brine generation vessel 
         [0046]      61  Agitator 
         [0047]      63  Brine stream 
         [0048]      65  Salt slurry (discharge) stream 
       DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0049]    Referring first to  FIGS. 1 and 6 , a preferred embodiment of a salt transport system  10  for a MEG recovery or reclamation process includes a flash separator  20  having a solids fluidization device  40  located at the bottom end  37  of the brine or downcomer column  29  and an on-off valve  33  located between the device  40  and the MEG/brine transition zone  31 . 
         [0050]    The flash separator  20  is of a kind well known in the art. In the separator  20  a rich (wet) MEG inlet stream  25  is brought into contact with a hot MEG recycle stream  35 . The MEG and water components of the rich MEG stream  25  are flashed and exit the upper end  21  of the separator  20  as a water and MEG vapor stream  27 . The salt components of the rich MEG inlet stream  25  precipitate in the brine column  29  of the separator  20 . A MEG/brine transition zone  31  forms in the column  29  between the MEG and the brine. 
         [0051]    Solids fluidization device  40  is arranged at the bottom end  37  of the column  29 . The device  40  includes means which produce or cause a swirling (e.g. vertiginous, rotary or cyclonic) motion or flow  51  of the motive fluid as it exits device  40 . One suitable device  40  is a HYDROTRANS™ solids fluidization and removal device (Cameron Process Systems, Houston, Tex.). Any other device may be used as the fluidization device provided the device creates a swirling (e.g., vertiginous, rotating, or cyclonic) motive fluid flow when the flow exits the device. 
         [0052]    Referring to  FIGS. 2-5 , the HYDROTRANS™ device includes a plurality of spaced-apart slots  45  arranged tangential to, surrounding, and in communication with an inner bore  47  which receives a motive fluid stream  49  at the lower inlet end  41  of the device. Motive fluid steam  49 —which can be a produced water or condensate water stream (or some combination thereof)—exits the slots  45  of device  40  as a swirling motive fluid stream  51 . The swirling motion of the motive fluid stream  51  mixes with the fluid containing solid/salt already residing in the column  29  to fluidize the salt components, thereby creating a salt slurry stream  53 . By way of example, during the first five minutes of operation, the concentration of salt in the device  40  can be about 20 vol % on average. 
         [0053]    Unlike a desanding hydrocyclone—which produce a cyclonic flow within the device but a straight over- and underflow exiting the device (i.e., straight in, cyclonic within, and straight out)—the solids fluidization device  40  produces this type of flow external to the device (i.e., straight in and rotary or cyclonic out). 
         [0054]    The removal device  55 , which can be a slurry discharge head, resides just above the upper end  43  of solids fluidization device  40 . Removal device  55  carries the salt slurry stream  53  to a brine generation tank or vessel  60 . 
         [0055]    Because the brine in the column  29  is saturated with salt, adding produced water to it causes the lower density (not saturated) produced water  49  to flow to the upper end  39  of the column  29  and MEG to flow to the bottom end  37 . This causes MEG loss. To prevent this loss from occurring, system  10  makes use of isolation means such as on-off valve  33 , which may be a butterfly-type valve. When the valve  33  is in the off or closed position, it prevents the produced water from flowing to the upper end  39  of the column  29 . The valve  33  isolates the fluid or brine located above and below the valve  33  from one another. 
         [0056]    Once the salts are removed from the bottom end  37  of the column  29 , the saturated brine in the brine generation vessel  60  is pumped back to the column  29  below the on-off valve  33  to replace the produced water. Once the produced water is replaced with the saturated brine, the on-off valve  33  is put in the on or open position to allow the salt to settle below the valve  33  and into the bottom  37  of column  29 . 
         [0057]    If a 1″ HYDROTRANS is used as device  40 , a flow rate of 4 m 3 /hr is required to remove the salt from the bottom end  37 . For about the first five minutes of operation, about 0.33 m 3  of a salt slurry stream  53  (about 20 vol %) to the brine generation vessel  60 . Assuming a void space of 40% between the salt particles (i.e., the salt represents 60%), the total amount of salt removed in five minutes (0.083 hr) is 0.04 m 3  (4 m 3 /hr×0.083 hr×0.2×0.6). The salt density is 2,165 kg/m 3 . Therefore, the amount of salt removed in five minutes of operation (i.e., with the valve  33  closed) is about 87 kg. If the amount of salt settled at the bottom end  37  is higher (or lower) than in the example, the removal process can be adjusted accordingly. 
         [0058]    System  10  does not require any centrifugal filters or desanding cyclones to remove salt from the brine column  29 , nor does it require centrifugal filtration, salt and centrate tanks, and density measurement devices. System  10  also requires less foot print than the prior art systems and methods, has lower construction costs, and is easier to operate and maintain. 
         [0059]    After the salt removal process is completed, an agitator  61  can be used to agitate and dissolve the salt in the liquid phase within the brine generation vessel  60 . The saturated brine solution can then be pumped as a saturated brine stream  63  to the column  29  to replace the produced water. Once this operation is complete, the valve  33  can be put in the on or open position to accumulate salt in the bottom end  37  of the column  29 . 
         [0060]    When the brine generation vessel  60  is filled with enough salt, agitator  60  will again be turned on to make a salt slurry stream  65  which is pumped to a water treating unit (not shown) or to overboard (if allowed). 
         [0061]    A method of removing salt from a rich MEG stream which makes use of system  10  includes the steps of:
       i. isolating fluid in the brine column  29  of the flash separator  20  by closing a valve  33  located above the bottom end  37  of the brine column  29  and below the upper end  39  of the column  29 ;   ii. introducing a swirling motive fluid stream  51  into the bottom end  37  of the brine column  29 , the swirling motive fluid stream  51  coming into contact with salt components residing in the column  29  and forming a salt slurry stream  53 ;   iii. removing the salt slurry stream  53  from the brine column  29  to a brine generation vessel  60 ;   iv. agitating the contents of the brine generation vessel  60  to form a saturated brine  63 ;   v. transferring the saturated brine  63  back to the column  29 ; and   vi. opening the valve  33  after step v is completed.       
 
         [0068]    Salt removal system  10  and the method for its use is an improvement over prior art systems and methods. The prior art makes use of complicated and expensive centrifugal filters or desanding cyclones to remove salt from the brine column  29  of the flash separator  20  along with centrifuge filtration, a salt tank, a centrate tank, and density measurement devices. 
         [0069]    While preferred embodiments of system  10  and a method for its use have been described in detail, the scope of the invention is defined by the following claims.