Abstract:
A secondary packing arrangement is provided for use with a well having a reciprocating pump and polished rod, and in combination with a stuffing box, the stuffing box being modified. Packing seals, a barrier fluid and a pressure transmitter cooperate with modified stuffing box components to regulate the pressure on either side of a packing seal. The barrier fluid is contained above the packing seal, with well fluids and accompanying pressures being contained below the packing seal, such that if leakage occurs, relatively clean barrier fluids are leaked instead of well fluids. The pressure across the packing seal is substantially balanced across the packing seal, or the well fluid side pressure is less than the barrier fluid side, thus reducing the occurrence of leakage and extending the life of the packing seal. Sources for the well fluids cooperating with the pressure transmitter include the well&#39;s flow line and casing.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
   This application claims priority from U.S. Provisional Patent Application Ser. No. 60/600,183, filed Aug. 10, 2004, the inventors being Randolph A. Busch and Harold H. Palmer. 

   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The field of the invention is reciprocating pump polished rod packing seals. 
   2. Description of Related Art 
   Over 75 percent of artificially lifted producing oil wells are being produced with sucker rod pumping systems, with the sucker rod string terminating in a polished rod that extends from the well head to the atmosphere. Stuffing boxes, having packing seals about the polished rod, are utilized to prevent well fluids from escaping around the polished rod. Well fluids include corrosive hydrocarbons including salt water and natural gas. 
   Due to the wear and tear of the moving polished rod, the corrosiveness of some well fluids, and the pressure drop across the packing seal in the stuffing box, all stuffing boxes on sucker rod pumping systems will leak at some time, requiring the primary packing seals in conventional stuffing boxes to be replaced periodically. 
   What is needed is a more simplified, unique, flexible, pressure-regulating secondary packing arrangement in a unitized assembly, readily adapted to any manufacturer&#39;s stuffing box in the field or on new installations. 
   SUMMARY OF THE INVENTION 
   The present invention overcomes the shortcomings of the prior art by providing apparatus for a secondary packing arrangement that, when used with a conventional stuffing box on a reciprocating plunger type pump having a polished rod, provides a pressure transmitter to create opposing pressures across a packing seal, the pressure being equal to or greater than the corresponding well fluid pressure at any given time during the pumping cycle. In some exemplary embodiments, the secondary packing arrangement includes a first chamber separated by a packing seal from a second chamber formed between the packing seal and the primary packing seal of the conventional stuffing box. The first chamber accepts well fluids, that in some exemplary embodiments are then routed to a pressure transmitter, which transmits the well fluids pressure to a more environmentally acceptable barrier fluid in the second chamber, such that when leakage occurs from the primary packing seal in the stuffing box, the leakage will be barrier fluid. Regulating the opposing pressures across the packing seal in this secondary packing arrangement provides the optimum operating condition for the packing seal elements, thus increasing the life of the elements. 
   In the case of the previously described secondary seal arrangement, i.e. the primary and secondary seals, the barrier fluid is sealed from the atmosphere, in some exemplary embodiments, by the primary seal in the conventional stuffing box. The consumption of the barrier fluid will be due mainly to leakage past the primary seal and evaporation of the barrier fluid film from the surface of the polished rod. Leakage past the primary seal is a function of the seal load and wear rate, for a given pressure. Increased seal load improves sealing, but also increases wear rate due to increased friction. The load, or squeeze, of the primary seal is adjusted by threaded bolts, and manually set by the operator. In order to reduce this operator induced uncertainty with respect to the rate of barrier fluid consumption, an alternative seal arrangement has been devised. 
   In such an exemplary embodiment (See  FIG. 11 ), an intermediate seal is placed in the lower housing, above the secondary seal, so as to reside between the primary and secondary seals. The load, or squeeze, of the intermediate seal is automatically set upon assembly and is not adjustable. The barrier fluid will then fill the area between the secondary and intermediate seals, and act to regulate the pressure across the secondary seal, just as in the previous seal arrangement. The intermediate seal, although exposed to a pressure differential at least equal to the well fluids pressure, will only come in contact with the clean barrier fluid. The primary seal will remain in place to contain the barrier fluid in the event of intermediate seal wear to the point of leakage. Since the primary seal will not need to be highly loaded, the decreased friction should result in less wear and reduced horsepower requirements. 
   The concept of hydro-balancing the pressure across the secondary seal of a stuffing box is the subject of Harold Palmour&#39;s U.S. Pat. No. 5,209,495 and U.S. Pat. No. 6,302,401. However, the present invention is a more simplified, unique, flexible pressure-balancing/regulating secondary packing arrangement in a unitized assembly, readily adapted to any manufacturer&#39;s stuffing box in the field or on new installations. 
   Additionally, the secondary packing arrangement of our invention prevents corrosive well fluids from contacting the packing seal elements in the conventional stuffing box, thus increasing the life of the packing seal elements in the stuffing box. 
   The application of this technology to sucker rod pumping systems will overcome the universal problem of losing production and polluting the area around the well head. 
   For a well producing at least first and second quantities of well fluids, and in combination with a reciprocating plunger type pump having a polished rod, and a stuffing box through which the polished rod moves, the stuffing box having a stuffing box packing seal, we have provided a secondary packing arrangement, through which the polished rod moves, the secondary packing arrangement, comprising: a housing having a top member and a chamber; a packing assembly, positioned within the housing chamber, through which the polished rod moves, the packing assembly having: a cylinder, the cylinder having an outer wall sealed against the housing; a packing seal, having at least one packing seal element, the packing seal having a top and a bottom, the packing seal and the cylinder dividing the housing chamber into a first chamber and a second chamber, the first chamber containing the first well fluid quantity, the second chamber in fluidic communication with the stuffing box packing seal; a retaining member supporting the packing seal, such that the first well fluid pressures the packing seal bottom; and a cap on the cylinder, the cap having fluid passages; a barrier fluid in the housing second chamber, the barrier fluid pressurably engaging the packing seal top through the cap fluid passages; and a pressure transmitter having a cylinder and a piston within the cylinder, the cylinder having a well fluid communication end, the well fluid communication end fluidically communicating with the second well fluid quantity such that the second well fluid quantity pressures the piston, the cylinder having a barrier fluid communication end, the barrier fluid communication end fluidically communicating with the housing second chamber, such that the barrier fluid pressurably engages the piston; the piston being sized such that the pressure from the second well fluid quantity on the piston is transmitted to the barrier fluid, the barrier fluid pressure opposing the first well fluid quantity pressure exerted by the first well fluid quantity on the packing assembly packing seal bottom. In some exemplary embodiments the barrier fluid pressure and the first well fluid quantity pressure are substantially balanced across the packing assembly packing seal. 
   In some exemplary embodiments the barrier fluid pressure is not less than the first well fluid quantity pressure, across the packing assembly packing seal. 
   In some exemplary embodiments the second well fluid quantity is routed from the housing first chamber to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a flow line transporting produced well fluids, and further wherein the second well fluid quantity is routed from the well flow line to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a casing, the well accumulating pressured gas in the casing, and further wherein the second well fluid quantity is routed from the casing to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the packing assembly cylinder has a top portion and bottom portion, the bottom portion being sealed against the housing and against the top portion and affixed within the housing chamber for no movement, the top portion being free for lateral movement, the packing seal being positioned within the cylinder top portion. 
   In some exemplary embodiments the housing top member bears upon the packing assembly cap, the barrier fluid passing laterally through the cap. 
   In some exemplary embodiments the secondary packing arrangement the packing assembly cylinder has an upper and lower portion, the upper portion having a groove, and further comprises an o-ring positioned within the groove for sealing the cylinder upper portion against the cylinder lower portion, and further comprises a wave spring positioned between the housing top member and the packing assembly cap, such that the housing top member bears upon the packing assembly cap through the wave spring, thereby maintaining a load on the cylinder upper portion and the o-ring. 
   In some exemplary embodiments the stuffing box threadably attaches to the housing top member. 
   In some embodiments, the barrier fluid is selected from the group consisting of hydrocarbon based, vegetable based, and animal fat based fluids. 
   In some exemplary embodiments the retaining member comprises a washer and a snap ring, the washer being sized for a clearance between the washer and the polished rod, the snap ring expanding against the cylinder and supporting the washer, the washer supporting the packing seal. 
   In some exemplary embodiments the pressure transmitter comprises means for adding additional barrier fluid. 
   In some exemplary embodiments the pressure transmitter cylinder well fluid communication end has a hole, and further comprising a rod attached to the pressure transmitter cylinder piston, the rod extruding through the cylinder well fluid communication end hole, such that, as the amount of barrier fluid in the cylinder barrier fluid communication end and the housing second chamber decreases, the rod extrusion from the cylinder is decreased. 
   In some exemplary embodiments the rod includes indicia related to the amount of barrier fluid. 
   In some exemplary embodiments the pressure transmitter cylinder barrier fluid communication end has a hole, and further comprising a rod attached to the pressure transmitter cylinder piston, the rod extruding through the cylinder barrier fluid communication end hole, such that, as the amount of barrier fluid in the cylinder barrier fluid communication end and the housing second chamber decreases, the rod extrusion from the cylinder is increased. 
   In some exemplary embodiments the rod includes indicia related to the amount of barrier fluid. 
   In some exemplary embodiments the well fluid is within the group consisting of water, oil, and hydrocarbon gas. 
   For a well producing at least first and second quantities of well fluids, and in combination with a reciprocating plunger type pump having a polished rod, and a stuffing box through which the polished rod moves, the stuffing box providing a stuffing box packing seal, we have provided a secondary packing arrangement through which the polished rod moves, the secondary packing arrangement comprising: a housing having a top member and a chamber; a packing assembly, positioned within the housing chamber, through which the polished rod moves, the packing assembly having: a cylinder, the cylinder having an outer wall sealed against the housing; a lower packing seal, having at least one packing seal element, the packing seal having a top and a bottom, the packing seal and the cylinder dividing the housing chamber into a first chamber and a second chamber, the first chamber containing the first well fluid quantity; a retaining member supporting the packing seal, such that the first well fluid quantity pressures the lower packing seal bottom; and a cap on the cylinder, the cap having: a first member and a second member, the polished rod moving through the first and second members, the first member having fluid passages; an intermediate packing seal, the intermediate packing seal being positioned adjacent the polished rod by the first and second members; the cap first member being sealed against the housing and against the second member, the cap defining a third chamber between the cap and the stuffing box packing seal; a barrier fluid in the housing second chamber, the barrier fluid pressurably engaging both the lower and intermediate packing seals through the cap second member fluid passages; and a pressure transmitter having a cylinder and a piston within the cylinder, the cylinder having a well fluid communication end, the well fluid communication end fluidically communicating with the second well fluid quantity such that the second well fluid quantity pressures the piston, the cylinder having a barrier fluid communication end, the barrier fluid communication end fluidically communicating with the housing second chamber, such that the barrier fluid pressurably engages the piston; the piston being sized such that the pressure from the second well fluid quantity on the piston is transmitted to the barrier fluid, the barrier fluid pressure opposing the first well fluid quantity pressure exerted by the first well fluid quantity on the packing assembly packing seal bottom. 
   In some exemplary embodiments barrier fluid pressure and the first well fluid quantity pressure are substantially balanced across the packing assembly packing seal. 
   In some exemplary embodiments the barrier fluid pressure is not less than the first well fluid quantity pressure, across the packing assembly packing seal. 
   In some exemplary embodiments the second well fluid quantity is routed from the housing first chamber to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a flow line transporting produced well fluids, and further wherein the second well fluid quantity is routed from the well flow line to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a casing, the well accumulating pressured gas in the casing, and further wherein the second well fluid quantity is routed from the casing to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the secondary packing arrangement further comprises a fitting for introducing a fluid into the third chamber. 
   In some exemplary embodiments the secondary packing arrangement further comprises a wick material positioned about the polished rod in the third chamber, for absorbing the introduced fluid in the third chamber and applying the fluid to the polished rod. 
   In some exemplary embodiments the introduced fluid is the same as the barrier fluid. 
   In some exemplary embodiments the fitting is a grease fitting. 
   For a well producing at least first and second quantities of well fluids, and in combination with a reciprocating plunger type pump having a polished rod, and a stuffing box through which the polished rod moves, the stuffing box having a stuffing box packing seal, we have provided a secondary packing arrangement through which the polished rod moves, the secondary packing arrangement comprising: a housing having a top member and a chamber; a packing assembly, positioned within the housing chamber, through which the polished rod moves, the packing assembly having: a packing seal, having at least one packing seal element; a packing seal compression member positioned within the lower housing above the at least one packing seal element, the packing seal being positioned to divide the housing chamber into a first chamber and a second chamber, the first chamber containing the first well fluid quantity, the second chamber in fluidic communication with the stuffing box packing seal, such that the first well fluid quantity pressures, the packing seal; and a compression member displacement mechanism for forcing the packing seal compression member toward the packing seal and compressing the packing seal; a barrier fluid in the housing second chamber, the barrier fluid pressurably engaging the packing assembly; and a pressure transmitter having a cylinder and a piston within the cylinder, the cylinder having a well fluid communication end, the well fluid communication end fluidically communicating with the second well fluid quantity such that the second well fluid quantity pressures the piston, the cylinder having a barrier fluid communication end, the barrier fluid communication end fluidically communicating with the housing second chamber, such that the barrier fluid pressurably engages the piston; the piston being sized such that the pressure from the second well fluid quantity on the piston is transmitted to the barrier fluid, the barrier fluid pressure opposing the first well fluid quantity pressure exerted by the first well fluid quantity on the packing assembly packing seal. In some exemplary embodiments the barrier fluid pressure and the first well fluid quantity pressure are substantially balanced across the packing assembly packing seal. 
   In some exemplary embodiments the barrier fluid pressure is not less than the first well fluid quantity pressure, across the packing assembly packing seal. 
   In some exemplary embodiments the second well fluid quantity is routed from the housing first chamber to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a flow line transporting produced well fluids, and further wherein the second well fluid quantity is routed from the well flow line to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a casing, the well accumulating pressured gas in the casing, and further wherein the second well fluid quantity is routed from the casing to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the compression member displacement mechanism extends through the housing top member. 
   For a well producing at least first and second quantities of well fluids, and in combination with a reciprocating plunger type pump having a polished rod, and a stuffing box through which the polished rod moves, we have provided a secondary packing arrangement through which the polished rod moves, the secondary packing arrangement comprising: the stuffing box, the stuffing box having: a top member and a lower housing forming a chamber; an upper packing seal positioned within the top member; a lower packing seal, the upper and lower packing seals each having at least one packing seal element; a lower packing seal compression member, the lower packing seal and compression member being positioned within the lower housing such that the lower packing seal divides the chamber into a first and second chamber, the first containing the first well fluid quantity, the second chamber in fluidic communication with the upper packing seal, such that the first well fluid quantity pressures the lower packing seal; and a compression member displacement mechanism for forcing the packing seal compression member toward the lower packing seal and compressing the lower packing seal; a barrier fluid in the housing second chamber between the upper packing seal and the lower packing seal, the barrier fluid pressurably engaging the lower packing seal; and a pressure transmitter having a cylinder and a piston within the cylinder, the cylinder having a well fluid communication end, the well fluid communication end fluidically communicating with the second well fluid quantity such that the second well fluid quantity pressures the piston, the cylinder having a barrier fluid communication end, the barrier fluid communication end fluidically communicating with the housing second chamber, such that the barrier fluid pressurably engages the piston; the piston being sized such that the pressure from the second well fluid quantity on the piston is transmitted to the barrier fluid, the barrier fluid pressure opposing the first well fluid quantity pressure exerted by the first well fluid quantity on the lower packing seal. 
   In some exemplary embodiments the barrier fluid pressure and the first well fluid quantity pressure are substantially balanced across the packing assembly packing seal. 
   In some exemplary embodiments the barrier fluid pressure is not less than the first well fluid quantity pressure, across the packing assembly packing seal. 
   In some exemplary embodiments the second well fluid quantity is routed from the housing first chamber to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a flow line transporting produced well fluids, and further wherein the second well fluid quantity is routed from the well flow line to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the well has a casing, the well accumulating pressured gas in the casing, and further wherein the second well fluid quantity is routed from the casing to the pressure transmitter cylinder well fluid communication end. 
   In some exemplary embodiments the compression member displacement mechanism extends through the housing top member. 
   For a well producing at least first and second quantities of well fluids, and in combination with a reciprocating plunger type pump having a polished rod, and a stuffing box through which the polished rod moves, the stuffing box having a stuffing box packing seal, we have provided a secondary packing arrangement, through which the polished rod moves, the secondary packing arrangement, comprising: a housing having a top member and a chamber; a packing assembly, positioned within the housing chamber, through which the polished rod moves, the packing assembly further comprising means for dividing the housing chamber into a first chamber and a second chamber, the first chamber containing the first well fluid quantity, the second chamber in fluidic communication with the stuffing box packing seal; a barrier fluid in the housing second chamber, and means for pressuring the barrier fluid such that the barrier fluid pressure on the packing assembly opposes the pressure exerted by the first well fluid quantity on the packing assembly. 
   In some exemplary embodiments, the secondary packing arrangement further comprises means for routing fluids from the housing first chamber for pressuring the barrier fluid. 
   In some exemplary embodiments the well has a flow line transporting well fluids, and the secondary packing arrangement further comprises means for routing fluids from the well flow line for pressuring the barrier fluid. 
   In some exemplary embodiments the well has a casing, the casing accumulating pressured hydrocarbon gas, and the secondary packing arrangement further comprises means for routing pressured gas from the well casing for pressuring the barrier fluid. 
   The foregoing features and advantages of our invention will be apparent from the following more particular descriptions of exemplary embodiments of the invention as illustrated, in some embodiments, in the accompanying drawings. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a sectional view of a conventional double pack stuffing box. 
       FIG. 2  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 3  is a sectional view of the lower housing in an exemplary embodiment of the present invention. 
       FIG. 4  is an enlargement of a portion of  FIG. 2 . 
       FIG. 5  is a sectional view of the packing assembly upper portion in an exemplary embodiment of the present invention. 
       FIG. 6  is a top view of the packing assembly upper portion in  FIG. 5 . 
       FIG. 7  is a sectional view of the packing assembly lower portion in an exemplary embodiment of the present invention. 
       FIG. 8  is a bottom view of the packing assembly lower portion in  FIG. 7 . 
       FIG. 9  is a sectional view of the packing assembly cap in an exemplary embodiment of the present invention. 
       FIG. 10  is a top view of the packing assembly cap in  FIG. 9 . 
       FIG. 11  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 12  is an enlargement of a portion of  FIG. 11 . 
       FIG. 13  is a bottom view of a packing assembly cap first member in an exemplary embodiment of the present invention. 
       FIG. 14  is a sectional view of the packing assembly cap first member in  FIG. 13 . 
       FIG. 15  is a sectional view of a packing assembly cap second member in an exemplary embodiment of the present invention. 
       FIG. 16  is a top view of the packing assembly cap second member in  FIG. 15 . 
       FIG. 17  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 18  is an enlargement of a portion of  FIG. 17 . 
       FIG. 19  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 20  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 21  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 22  is a partially sectional view of an exemplary embodiment of the present invention. 
       FIG. 23  is a sectional view of a conventional double pack stuffing box packing seal. 
       FIG. 24  is a sectional view of a conventional double pack stuffing box compression ring. 
       FIG. 25  is a partially sectional view of an exemplary embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 
   The following discussion describes exemplary embodiments of the invention in detail. This discussion should not be construed, however, as limiting the invention to those particular embodiments. Practitioners skilled in the art will recognize numerous other embodiments as well. For a definition of the complete scope of the invention, the reader is directed to the appended claims. 
   Referring now to  FIG. 1 . A typical polished rod  10  extends from the well head and through a conventional double pack stuffing box  12 . This stuffing box has two packing seal  13 ,  14  with each seal having at least two packing seal elements. The packing seal is commercially available and typically referred to as cone or dome packing. Tightening the bolts  15  presses the packing seal  14  against the polished rod by being turned against a packing seal compression ring  14   a . The stuffing box has a lower housing  16  with a threaded end  17  for connecting to the well head, such that well fluids will enter the annulus  18  about the polished rod, from the well head fluid outlet below. The stuffing box also has an upper housing  19 , encompassing the packing seal  13 . A typical well will have a flow line leading from the well head for transporting well fluids, the well fluids typically including oil, salt water, and/or hydrocarbon gas. Such a flow line is in fluid communication with the well head fluid outlet to which the stuffing box is attached. Furthermore, a typical well will have a casing, in which well fluids, in the form of hydrocarbon gas, are accumulated under pressure. 
   Referring now to  FIG. 2 , an exemplary embodiment of the secondary packing arrangement device  30  of the present invention is illustrated in combination with a conventional single pack stuffing box  20  having a packing seal  21  with four packing seal elements. In the conventional single pack stuffing box, when bolts  22  are tightened the packing seal is pressed against the polished rod  10 . The stuffing box has a lower housing  23  with a threaded end  24  that, in a conventional installation, attaches to the well head such that an annulus  25  is formed about the polished rod. 
   In the exemplary embodiment shown in  FIG. 2  and in a closer view in  FIG. 14 , the secondary packing arrangement  30  has a housing including a lower housing  32  that can readily be adapted from the lower housing  16  of the conventional double pack stuffing box shown in  FIG. 1 , with only slight resizing of the interior. The lower housing is shown in more detail in  FIG. 3 . The lower housing has a lower end  33  that threadably attaches to the wellhead at a well fluid outlet such that well fluids enter the lower housing. Bolted to the lower housing  32  is a top member  34  with an adapter  36  for threadably receiving the conventional single pack stuffing box lower housing end  24 . The secondary packing arrangement housing forms a chamber  38  that is in fluid communication with the stuffing box packing seal  21 . The lower housing  32  has three threaded outlets  40 , 42 , 44 , a first shoulder  46  and a second shoulder  48 . The bolted joinder of the housing top member  34  to the lower housing  32  is sealed by a conventional O-ring  49  adjacent the second shoulder  48 . 
   As further illustrated in  FIG. 2  and  FIG. 4 , this exemplary embodiment of the secondary packing arrangement  30  includes a packing assembly  50 , positioned within the housing chamber  38 , through which the polished rod  10  moves. In this exemplary embodiment, the packing assembly includes a cylinder having a top portion  52 , shown in more detail in  FIG. 5  and  FIG. 6 . As shown therein, the top portion is shown to have an open bottom  54 , a groove  56  for accepting an O-ring  58 , and a groove  60  for accepting a conventional snap ring  62 . The snap ring supports a conventional washer  64 , the washer sized to create a clearance  66  between the washer and the polished rod  10 . The snap ring and washer retain a packing seal, which includes three conventional packing seal elements  68  positioned within the cylinder upper portion. These packing seal elements seal against the polished rod, preventing well fluid passage through the packing assembly cylinder upper portion. 
   In the exemplary embodiment illustrated in  FIG. 4 , the packing assembly cylinder also includes a bottom portion  70 , shown in more detail in  FIG. 7  and  FIG. 8 . The cylinder bottom portion has an opening  72 , eight fluid passages  74 , and a groove  76  in its outer wall  78  for positioning an O-ring  80  against the lower housing interior, thus sealing the annulus around the cylinder bottom portion  70  to prevent well fluids from passing to the annulus about the cylinder upper portion  52 . The cylinder bottom portion also includes an upper surface  82  against which the cylinder upper portion  52  seals using the O-ring  58 . These two seals, along with the seal between the polished rod and the packing seal elements  68 , effectively divide the housing chamber  38  into a first chamber  84  and a second chamber  86 , well fluids being present in the first chamber only. 
   In this exemplary embodiment of  FIG. 2  and  FIG. 4 , the packing assembly  50  also includes a cap  90 , shown in more detail in  FIG. 9  and  FIG. 10 . The cap has an opening  92  and eight fluid passages  94 . The cap fits on the top of the cylinder upper portion  52 , and a conventional wave spring  96  is positioned between the cap and the cylinder upper portion. During installation of the secondary packing arrangement  30 , the cap and the cylinder upper portion are free to simultaneously move along the top surface of the cylinder bottom portion  70  without breaking the seal between the cylinder upper and bottom portions. This allows optimum positioning of the packing seal elements  68  with respect to the polished rod  10 . The housing top portion bears upon the cap as it is tightened, compressing wave spring  96 , thereby loading O-ring  58  and maintaining a seal between cylinder upper and bottom portions. 
   In the exemplary embodiment of the present invention depicted in  FIG. 2  and  FIG. 4 , the second chamber  86  is filled with a barrier fluid, which moves in the second chamber and through the cap  90  fluid passages  94  such that the barrier fluid contacts the packing seal, and any pressure within the second chamber acts on the packing seal elements. 
   A pressure transmitter  100  is provided in the exemplary embodiment of the present invention shown in  FIG. 2 . The transmitter sits in a base  101  that is attached to the housing top portion  34  using a bracket  102 . The transmitter includes a cylinder  104  and a piston  106  within the cylinder. Attached to the piston is a rod  108  that screws into a nut  110  mounted in the piston. The rod extends from the cylinder through hole  112  with an elastomer seal. A hose  114  with a valve  116  extends from one of the lower housing outlets in the housing first chamber  84 , and enters a well fluid communication end of the cylinder through inlet  118 , establishing communication of well fluids and well fluids pressure from the well fluid outlet, through the housing first chamber, into the cylinder, and to the top of the piston. During installation the grease fitting  120  allows the operator to fill the housing second chamber  86  and the barrier fluid communication end of the cylinder below the piston with barrier fluid. A hose  122  extends from a cylinder barrier fluid communication end outlet  124  to one of the lower housing outlets  40 , thus establishing barrier fluid communication between the housing second chamber and the cylinder below the piston. 
   In the exemplary embodiment illustrated in  FIG. 2 , the pressure transmitter piston  110  is sized such that the pressure from the well fluid on the piston is transmitted to the barrier fluid, resulting in the desired regulation of pressure across the packing assembly packing seal. 
   The rod  108  extruding from the cylinder  104  in the exemplary embodiment illustrated in  FIG. 2  provides an indication as to the amount of barrier fluid. The greater the extended length, the more barrier fluid is present. In some exemplary embodiments, appropriate indicia are provided on the rod to provide information to the operator as to required addition of barrier fluid. In some exemplary embodiments, the rod is of sufficient size that it can be viewed by the operator from a distance. 
   In some exemplary embodiments, and as shown in  FIG. 2 , a pressure gauge  126 , with valve  128  and related attachment fittings  130 , is attached to the housing through one of the lower housing outlets  44 , allowing the operator to determine the pressure in the housing second chamber  86 , the pressure being then comparable by the operator to conventional well head pressure gauges (reflecting pressure in the housing first chamber  84 ) to confirm the proper regulation of pressure across the packing seal  50 . 
   In another exemplary embodiment of the present invention, depicted in  FIG. 11  and in more detail in  FIG. 12 , a different packing assembly cylinder upper portion  202  and cap  204  are provided. The cylinder upper portion  202  is reduced in height and encloses two packing seal elements  205 . The snap ring  62  and the washer  64  are unchanged and support the packing seal elements as in the previously described exemplary embodiment. The cylinder upper portion  202  is free for sealed lateral movement and positioning during installation. Similarly, the packing assembly lower portion  70  seals against the housing to divide the housing into the first chamber  84  and the second chamber  86 . 
   In the exemplary embodiment shown in  FIG. 12 , the cap  204  includes a first member  206 , shown in more detail in  FIG. 13  and  FIG. 14 . The first member includes an opening  208  sized to create the clearance  210  between the first member opening and the polished rod  10 . The first member has eight fluid passages  212  and a groove  214  for positioning an O-ring  216 . The packing assembly cap second member  220 , shown in more detail in  FIG. 15  and  FIG. 16 , includes an opening  222  for the polished rod and a groove  224  for positioning an O-ring  226 . 
   In this exemplary embodiment  200 , the O-ring  216  seals the packing assembly cap first member  206  against the second member  220 , and the O-ring  226  seals the second member against the housing top portion  34 . The first and second members mate to form a space for positioning an intermediate packing seal member  228  about the polished rod, the intermediate packing seal member integrating an O-ring  230  for energizing the seal member against the polished rod  10 . Unlike the cap  90  of the previous embodiment, the cap  204  in this exemplary embodiment does not have a fluid passage for allowing barrier fluid to contact the packing seal  21  of the conventional stuffing box  20 . Instead, the cap  204  cooperates with the opening in the housing top member  34  to form a third chamber  232  between the cap second member, the intermediate packing seal member and the packing seal  21  of the stuffing box. The intermediate packing seal prevents barrier fluid from the second chamber from entering the third chamber. The intermediate packing seal load is automatically set upon installation and is not adjustable. 
   In another exemplary embodiment, of the type depicted in  FIG. 17  and shown in more detail in  FIG. 18 , the housing top portion  302  is modified to include an outlet  304  from the third chamber  232 , the outlet being adapted to receive a grease fitting  306 . During installation the operator fills the third chamber with a barrier fluid, such as grease, and also positions a wick-type material about the polished rod  10  in the third chamber for soaking in the fluid and lubricating the polished rod. 
   Refer again to the exemplary embodiment depicted in  FIG. 2  and  FIG. 4 , and the pressure transmitter  100 , the hose  114 , with valve  116 , connected to inlet  118  on the well fluid communication end of the transmitter cylinder  104 , the hose  122  connected to outlet  124  on the barrier fluid communication end of the transmitter cylinder  104 , and the grease fitting  120 . In another exemplary embodiment  30   a , of the type depicted in  FIG. 19 , a hose  114   a  connects to outlet  124   a  on what is now the well fluid communication end of the transmitter  100   a  cylinder  104   a , a hose  122   a  connects to inlet  118   a  on what is now the barrier fluid communication end of the transmitter cylinder  104   a , and the grease fitting  120   a  is positioned on the barrier fluid communication end of the transmitter cylinder  104   a . This reversal of hoses to the transmitter results in the barrier fluid, such as grease, being present in the top (barrier fluid communication end) of the transmitter where the seal about the indicator rod  108   a  is located at the hole  112  (see  FIG. 2 ) in the transmitter cylinder  104   a . Should this seal leak, the leaked fluid will be the relatively clean barrier fluid, instead of well fluids. 
   Similarly, refer again to the exemplary embodiment depicted in  FIG. 11  and  FIG. 12 , having corresponding pressure transmitter components with the exemplary embodiment of  FIG. 2 , i.e. the pressure transmitter  100 , the hose  114 , with valve  116 , connected to inlet  118  on the well fluid communication end of the transmitter cylinder  104 , the hose  122  connected to outlet  124  on the barrier fluid communication end of the transmitter cylinder  104 , and the grease fitting  120 . In another exemplary embodiment  200   a , of the type depicted in  FIG. 20 , a hose  114   a  connects to outlet  124   a  on what is now the well fluid communication end of the transmitter  100   a  cylinder  104   a , a hose  122   a  connects to inlet  118   a  on what is now the barrier fluid end of the transmitter cylinder  104   a , and the grease fitting  120   a  is positioned on the barrier fluid communication end of the transmitter cylinder  104   a . This reversal of hoses to the transmitter results in the barrier fluid, such as grease, being present in the top (barrier fluid communication end) of the transmitter where the seal about the indicator rod  108   a  is located at the hole  112  (see  FIG. 2 ) in the transmitter cylinder  104   a . Again, should this seal leak, the leaked fluid will be the relatively clean barrier fluid, instead of well fluids. 
   Similarly, refer again to the exemplary embodiment depicted in  FIG. 17  and  FIG. 18 , having corresponding pressure transmitter components with the exemplary embodiment of  FIG. 2 , i.e. the pressure transmitter  100 , the hose  114 , with valve  116 , connected to inlet  118  on the well fluid communication end of the transmitter cylinder  104 , the hose  122  connected to outlet  124  on the barrier fluid communication end of the transmitter cylinder  104 , and the grease fitting  120 . In another exemplary embodiment  300   a , of the type depicted in  FIG. 21 , a hose  114   a  connects to outlet  124   a  on what is now the well fluid communication end of the transmitter  100   a  cylinder  104   a , a hose  122   a  connects to inlet  118   a  on what is now the barrier fluid communication end of the transmitter cylinder  104   a , and the grease fitting  120   a  is positioned on the barrier fluid communication end of the transmitter cylinder  104   a . This reversal of hoses to the transmitter results in the barrier fluid, such as grease, being present in the top (barrier fluid communication end) of the transmitter where the seal about the indicator rod  108   a  is located at the hole  112  (see  FIG. 2 ) in the transmitter cylinder  104   a . Again, should this seal leak, the leaked fluid will be the relatively clean barrier fluid, instead of well fluids. 
   In exemplary embodiments of the type depicted in  FIGS. 19-21 , the reversal of the hoses  114   a ,  122   a  results in barrier fluid being in the end of the pressure transmitter cylinder  104  through which the indicator rod  108   a  extends. As a result, a decrease in the amount of barrier fluid causes the indicator rod to extend further from the cylinder. 
   Turning to  FIG. 22 , an additional exemplary embodiment of a secondary packing arrangement  400  is illustrated in combination with a conventional single pack stuffing box  20  having a packing seal  21  with four packing seal elements. In the conventional single pack stuffing box, when bolts  22  are tightened the packing seal is pressed against the polished rod  10 . The stuffing box has a lower housing  23  with a threaded end  24  that, in a conventional installation, attaches to the well head such that an annulus  25  is formed about the polished rod. 
   In exemplary embodiments of the type shown in  FIG. 22 , the secondary packing arrangement  400  has a housing  402  including a lower housing  404  that can readily be adapted from the lower housing  16  of the conventional double pack stuffing box shown in  FIG. 1 , with only slight modification. The lower housing  404  has a lower end  406  that threadably attaches to the wellhead at a well fluid outlet such that well fluids enter the lower housing. Bolted to the lower housing  404  is an upper housing  408  with an adapter  410  for threadably receiving the conventional single pack stuffing box lower housing end  24 . Bolts  411  (one shown) are provided for bolting the upper housing  408  to the lower housing  404 . As part of a packing assembly  412 , two bolts  414  (one shown) are positioned by the upper housing  408  in a manner similar to the two bolts  15  shown in the conventional double pack stuffing box  12  depicted in  FIG. 1 . The housing  402  forms a chamber  416 , and within the housing chamber, and as part of the packing assembly  412 , is a packing seal  418  and a packing seal compression ring  420 . The packing seal and compression ring  418 , 420  are, in some exemplary embodiments, the same as the packing seal  14  and compression ring  14   a , shown in  FIG. 1 . Additional, sectional views of the packing seal  14  and the compression ring  14   a , are provided in  FIG. 23  and  FIG. 24 , respectively. 
   In exemplary embodiments of the type illustrated in  FIG. 22 , the bolts  414  turn against the compression ring  420  forcing the packing seal  418  to seal against the polished rod  10 . The bolted joinder of the upper housing  408  to the lower housing  404  is sealed by a conventional O-ring  422  positioned on a shoulder  424  of the lower housing. Although the upper housing  408  positions bolts  414  in a manner similar to the positioning of bolts  15  in the upper housing  19  of the conventional double pack stuffing box  12 , the upper housing  408  no longer is configured to contain a packing seal such as the packing seal  13  positioned with the upper housing of the conventional stuffing box. 
   Refer again to the  FIG. 19  and the hoses  114   a , 122   a . A hose  122   a  is provided in exemplary embodiments of the type illustrated in  FIG. 22  and is similarly routed as the hose  122   a  in  FIG. 19 . However, in some such exemplary embodiments, a hose  426  communicates well fluids using a conventional connection to another well fluid outlet on a flow line (not shown), instead of routing such well fluids from the chamber  428  below the packing assembly  412 , as was the manner utilized in the exemplary embodiment of  FIG. 19 , using the hose  114   a . This configuration continues to use the pressure transmitter  100  to regulate the pressures between the well fluids and the barrier fluid on either side of the packing assembly  412 . 
   Similarly, in some exemplary embodiments of the type illustrated in  FIG. 22 , the hose  426  communicates well fluids using a conventional connection to another well fluid outlet on the casing (not shown). 
   In some exemplary embodiments of the kind depicted in  FIG. 22 , a pressure gauge  126 , valve  128 , and related attachment fittings  130  are provided, in a similar fashion to the pressure gauge  126 , valve  128 , and related attachment fittings  130  depicted in  FIG. 19 . 
   Turning now to  FIG. 25 , an exemplary embodiment of the secondary packing arrangement of the present invention is depicted, and is shown in combination with a conventional double pack stuffing box  502  of the type depicted in  FIG. 1 . In exemplary embodiments of the type shown in  FIG. 25 , the device has a housing  502 , the housing having an upper housing  504  and a lower housing  506 , the lower housing forming a chamber  508 . The lower housing  506  has a lower end  510  that threadably attaches to the wellhead at a well fluid outlet such that well fluids enter the lower housing. Bolts  512  (one shown) are provided for bolting the upper housing  504  to the lower housing  506 . As part of a packing assembly  514 , two bolts  516  (one shown) are positioned by the upper housing in a manner similar to the two bolts  15  shown in the conventional double pack stuffing box  12  depicted in  FIG. 1 . Within the housing chamber  508 , and as part of the packing assembly  514 , is a packing seal  518  and a packing seal compression ring  520 . The packing seal and compression ring  518 , 520  are, in some exemplary embodiments, the same as the packing seal  14  and compression ring  14   a , shown in  FIG. 1 . 
   In exemplary embodiments of the type illustrated in  FIG. 25 , the bolts  516  turn against the compression ring  520  forcing the packing seal  518  to seal against the polished rod  10 . The bolted joinder of the upper housing  504  to the lower housing  506  is sealed by a conventional O-ring  522  positioned on a shoulder  524  of the lower housing. The upper housing  504  positions bolts  516  in a manner similar to the positioning of bolts  15  in the upper housing  19  of the conventional double pack stuffing box  12 , and the upper housing  504  is configured to contain a packing seal such as the packing seal  13  positioned with the upper housing of the conventional stuffing box. 
   Refer again to the  FIG. 19  and the hoses  114   a , 122   a . A hose  122   a  is provided in exemplary embodiments of the type illustrated in  FIG. 25  and is similarly routed as the hose  122   a  in  FIG. 19 . However, in some such exemplary embodiments, a hose  426  communicates well fluids using a conventional connection to another well fluid outlet on a flow line (not shown), instead of routing such well fluids from the chamber  508  below the packing assembly  514 , as was the manner utilized in the exemplary embodiment of  FIG. 19 , using the hose  114   a . This configuration continues to use the pressure transmitter  100  to balance the pressures exerted by the well fluids and the barrier fluid on either side of the packing assembly  514 . 
   Similarly, in some exemplary embodiments of the type illustrated in  FIG. 22 , the hose  426  communicates well fluids using a conventional connection to another well fluid outlet on the casing (not shown). 
   In some exemplary embodiments of the kind depicted in  FIG. 25 , a pressure gauge  126 , valve  128 , and related attachment fittings  130  are provided, in a similar fashion to the pressure gauge  126 , valve  128 , and related attachment fittings  130  depicted in  FIG. 19 . 
   In some exemplary embodiments of the kind illustrated in  FIG. 2 ,  FIG. 11 ,  FIG. 17 ,  FIG. 19 ,  FIG. 20 , and  FIG. 21 , a quantity of well fluids is routed to the pressure transmitter cylinder well fluid communication end from a well fluid outlet on a well flow line or from a well fluid outlet on a well fluid outlet from the well casing, eliminating the need for the hose leading from the housing first chamber. 
   In some exemplary embodiments of the kind illustrated in  FIG. 22  and  FIG. 25 , a quantity of well fluids is routed to the pressure transmitter cylinder well fluid communication end from the housing first chamber. 
   In some exemplary embodiments and applications of the present invention the barrier fluid is either hydrocarbon based, a hydrocarbon based grease, non-hydrocarbon based, vegetable based, or animal fat based. In some exemplary embodiments and applications, the well fluid includes hydrocarbons, oil, hydrocarbon gas, and/or water. 
   With respect to the above description then, it is to be realized that the optimum apparatus for a particular application, will include elastomer seals, piping, fittings, hoses, barrier fluids, and other seal materials, which will occur to those skilled in the art upon review of the present disclosure. 
   All equivalent relationships to those illustrated in the drawings and described in the specification are intended to be encompassed by the present invention. 
   The descriptions in this specification are for purposes of illustration only and are not to be construed in a limiting sense. The scope of the present invention is limited only by the language of the following claims.