Abstract:
An inlet assembly for introducing a sample into a carrier gas stream for gas chromatography is disclosed including a housing having a bore that receives a liner. A sealing member having a core with a surface layer is positioned within the bore in sealing engagement with the bore and the liner. The surface layer of the sealing member has a lower adhesion to the housing than the core. The surface layer facilitates removal of the sealing member and the liner from the bore. A method of replacing an existing liner in an inlet assembly for chromatography is also disclosed. The method includes providing a liner with a sealing member having a core with a surface layer having a lower adhesion to the housing than the core, removing the existing liner from the bore and inserting a new liner with a new sealing member into the bore.

Description:
BACKGROUND 
   In one typical application of gas chromatography, a process by which one or more components from a chemical mixture may be separated and identified, a carrier gas, for example, an inert gas such as nitrogen or helium, flows through a tube known as a column. Large size columns may be packed with an inert packing medium coated with an active substance that interacts with components in the chemical mixture being analyzed. Smaller capillary columns are often coated on their inner surface with the active substance. A sample of the chemical mixture to be analyzed is introduced into the column. As the sample is swept through the column with the carrier gas, the different components, each one having a different affinity for the active substance lining the column or coating the packing medium, move through the column at different speeds. Those components having greater affinity for the active substance move more slowly through the column than those having less affinity, and this speed differential results in the components being separated from one another as they pass through and exit the column. 
   In the foregoing typical application, the carrier gas with the separated components exits the column and passes through a detector. Various types of detectors may be used, including a thermal conductivity detector, a flame ionization detector, electron capture detector, flame photometric detector, photo-ionization detector and a Hall electrolytic conductivity detector. A two dimensional plot of the detector measurements against elution time or volume, known as a chromatogram, may be made, and from the chromatogram or the digital representation thereof the components may be identified. 
   Introduction of the sample chemical mixture into the column may be effected using a sample inlet assembly. The inlet assembly has a bore in fluid communication with both a source of the carrier gas and the column. An injection port mounted on the inlet assembly is in fluid communication with the bore. The injection port receives a syringe for injecting the sample into the bore. Carrier gas flows from the source through the bore and into the column. The sample is injected into the bore where it is borne by the carrier gas into the column. The sample may initially be in a liquid state, and then vaporized to a gaseous state by the application of heat within the inlet assembly. 
   The bore has a removable liner made of glass or other substantially inert material to guard against contamination of the sample, which may react with the material comprising the inlet assembly. A seal, for example, an elastomeric O-ring, is positioned between the liner and the bore. 
   SUMMARY 
   The invention concerns a sealing member positionable between a liner and a bore of a chromatography inlet assembly. The sealing member comprises a core having a surface layer. The surface layer has a lower coefficient of friction than the core and facilitates removal of the sealing member from the bore. 
   The invention may also include an inlet assembly for introducing a sample into a carrier gas stream for gas chromatography. The inlet assembly is connectable to a chromatography column and includes a housing having a bore with an inner surface. A removable liner is positioned within the bore. The liner has an outer surface which may be in spaced relation to the inner surface of the bore. A sealing member is positioned within the bore in sealing engagement with the inner and outer surfaces. The sealing member has a core with a surface layer. The surface layer has a lower coefficient of friction than the core, which facilitates removal of the sealing member from the bore. 
   The invention also includes a method of replacing an existing liner in an inlet assembly for chromatography. 
   The method comprises: 
   
       
       
         
           providing a liner having a sealing member comprising a core having a surface layer with a lower coefficient of friction than the core; 
           removing the existing liner from the bore of the inlet assembly; and 
           inserting the new liner with the sealing member into the bore. 
         
       
     
  

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a longitudinal sectional view of a sample inlet assembly embodiment according to the invention; and 
       FIG. 2  is a cross sectional view of a sealing member embodiment according to the invention. 
   

   DETAILED DESCRIPTION 
     FIG. 1  shows an embodiment of a sample inlet assembly  10  according to the invention and used for gas chromatography. Inlet assembly  10  comprises a housing  12 , also known as an inlet assembly weldment. Housing  12  is often formed from stainless steel which provides a durable, robust design that mitigates contamination of samples being analyzed. Use of metal for the housing confers additional advantages as explained below. 
   A bore  14  having an inner surface  16  extends through housing  12 . A liner  18  is positioned within the bore. The liner is often formed from an inert material, for example, glass or fused quartz, and helps to mitigate contamination of the gas sample and carrier gas passing through the bore. Liner  18  has a diameter that is smaller than the diameter of the bore, and together the outer surface  19  of the liner and the inner surface  16  of the bore define an annular duct  20  that extends along bore  14 . Duct  20  provides a fluid flow path for gas that does not pass through the column, and thus enables the flow to be split as described in detail below. 
   The upstream end  22  of housing  12  has a carrier gas inlet  24  that is in fluid communication with a source of carrier gas  26  through a conduit  28 . Carrier gas inlet is in fluid communication with bore  14  through the liner  18 . A gas outlet  30  is also positioned on the housing  12 , the outlet  30  being in fluid communication with the annular duct  20  between the bore and the liner. 
   The upstream end  22  of housing  12  also has a sample inlet  32  in fluid communication with bore  14  through the liner  18 . Sample inlet  32  includes a septum  34  that is exposed to the ambient. Septum  34  overlies an inlet seat  36  that interfaces with the liner  18 . An aperture  38  extends through the inlet seat to permit a syringe needle  40  to be inserted into the liner  18  and introduce the sample into the sample inlet assembly  10 . The syringe needle penetrates the septum  34  before it passes through aperture  38 . The septum is a solid body formed of a soft polymer material. The material permits the needle to pass through but “heals” itself by closing any opening formed by the needle, thereby allowing the septum to act as a seal for the inlet seat  36  that prevents gases from exiting to the ambient through aperture  38 . Both the inlet seat  36  and the septum  34  are secured to the housing  12  by respective retaining nuts  42  and  44 , allowing for removal of the seat and the septum as well as the liner  18 . 
   A heating element  46  and a thermistor  48  are mounted on the housing  12 . The heater is electrically powered and heats the housing to the temperature required to vaporize any liquid sample to the gaseous state. The thermistor measures the housing temperature and provides feedback information to help maintain the housing at a desired temperature appropriate to the sample being analyzed. 
   A chromatography column  50  is connected to the downstream end  52  of the inlet assembly  10 . Large columns may have inner diameters between about 3 mm and about 8 mm and lengths between about 1 meter and about 3 meters. Capillary columns (as shown) may have inner diameters between about 0.05 mm and about 1 mm and may be 100 meters or more in length. Column  50  is in fluid communication with the bore  14  through the liner  18  and conducts the carrier gas and sample passing through the bore to a chromatograph  54 , indicated schematically. Fluid communication between the column  50  and the bore  14  is effected by a sealing plate  56  that engages the downstream end of the inlet assembly to seal the bore  14 . Sealing plate  56  is held in position by a retaining nut  58 . The column  50  has a ferrule  60  that engages a seat  62  on the sealing plate  56 . The ferrule  60  is kept engaged with the seat  62  by a retaining nut  64 . 
   To enable split flow of the gases through the inlet assembly there is a gas space  66  between the end  68  of liner  18  and the sealing plate  56 . Gas space  66  provides fluid communication between the liner  18  and the annular duct  20 . This allows a portion of the gases to bypass the intake  50   a  of column  50 , exit the liner  18  into the gas space  66  and then travel along the annular duct  20  to exit the inlet assembly  10  through the gas outlet  30 . The proportion of the gas that passes through the column may be controlled by throttling the gas outlet  30 . 
   A sealing member  70  is positioned within bore  14 . Sealing member  70  isolates the interior of the liner  18  from the bore  14  to ensure that the gas flow proceeds downstream through the liner to the column  50 , and, for the portion of the gas not entering the column, upstream through annular duct  20  to the gas outlet  30 . 
   Sealing member  70  is an O-ring in sealing engagement with the outer surface  19  of liner  18  and the inner surface  16  of bore  14 . A typical O-ring seal used with a chromatography inlet assembly is shown in  FIG. 2  and has a torroidal shape and may have an inner diameter of about 0.239 inches defining a central space  72  for receiving the liner. The thickness of the O-ring is about 0.070 inches. A durometer of about 75 on the Shore A scale has shown itself to be practical for such seals. 
   Sealing member  70  is formed from a fluorocarbon rubber compound, that is, a fluorocarbon polymer which exhibits sufficient elasticity to allow it to act as a seal in the gas chromatograph environment as described herein. An example of such a fluorocarbon rubber compound is supplied by DuPont under the trade name Viton. Viton is used with analysis samples formed of chemically aggressive compounds such as chlorinated solvents, benzene, toluene, alcohols, hexane and heptane because it is substantially impervious to chemical attack by such compounds. Viton is also useful in view of its ability to form an effective seal even at the elevated temperatures (300 degrees C. or greater) required to volatilize the-sample components for gas chromatography. 
   Over time, after many cycles of heating and cooling of the inlet assembly, the fluorocarbon rubber seal  70  may adhere to the inner surface  16  of bore  14 . This makes it difficult to remove the liner  18 , for example, to replace an old, contaminated liner with a new one. Adhesion between the sealing member and the bore may also cause particles of fluorocarbon rubber to be left on the inner surface of the bore, and these particles can contaminate the gases flowing through the inlet assembly and may adversely affect column performance. 
   To avoid these problems the sealing member  70  is treated so that, as shown in  FIG. 2 , it has a polymerized surface layer  74  surrounding a core  76 . The surface layer  74  exhibits lower adhesion to the housing than the untreated core  76 . One way of evaluating the adhesion of the sealing member to the housing is to measure the coefficient of friction of the surface layer in comparison with that of the core. The treated surface layer has a lower coefficient of friction than the untreated material forming the core and therefore exhibits the desired non-stick characteristics. The non-stick characteristic of the surface layer prevents the seal from adhering to the inner surface  16  of bore  14  and thus facilitates removal and replacement of liners  18  in addition to mitigating contamination of the inlet assembly by leaving particles of the sealing member behind upon removal of the liner. 
   Because the surface layer  74  is very thin (on the order of microns in thickness) the sealing member substantially retains the desired physical characteristics, such as resistance to chemical attack and relatively high melting point associated with the core material, but also will not stick to the housing  12 . 
   Surface layer  74  is formed by plasma treatment of the sealing member  70 . Plasma treatment is effected by electrically energizing a process gas at low pressures (1-100 Pa) within a vacuum chamber in which the sealing member  70  is positioned. The atoms or molecules forming the process gas are ionized, and the molecules may be fragmented, and thus the process gas becomes highly reactive and will readily react chemically with the exposed surfaces of the sealing member. 
   Specific surface properties on the sealing member may be obtained through the choice of the process gas as explained in the technical papers  Plasmapolymerization Preteratment and Finishing of Polymer Surfaces in the Field of Medical Plastics , Sep. 9, 2004, Europlasma, Oudenaarde, Belgium, and  A New Alternative for Better Modification of Medical Surfaces and Textiles , Aug. 5, 2004, Europlasma, Oudenaarde, Belgium, both articles being hereby incorporated by reference. Reduction of the surface friction coefficient to ensure the desired non-stick characteristics is obtained by gases which effect a surface deposition or polymerization layer on the sealing member. The molecular structure in the surface layer  74  is highly cross-linked and built up from the ions and fragments of the process gas, formed into a plasma by the energy of the electrical discharge within the vacuum chamber. Plasma polymerization, as opposed to other plasma processes (such as surface activation, modification, etching, and degreasing) uses process gases, both alone and in combination, including hydrocarbons such as acetylene, ethane, ethylene, and methane, chemical analogues of these gases for example formed by substituting suitable elements for the carbon atoms as are known to those of skill in the art. Other analogues include fluorocarbon gases such as C 2 F 4 , C 2 F 6  and the like, again used either alone or in combination with one another or with the hydrocarbons mentioned above. Interaction between the process gas plasma fragments and the surface of the sealing member produces chemically stable structures in the surface layer  74  while removing unstable chemical structures by the reaction with chemically active fragments to form the desired surface characteristics. Chromatography Research Supplies, Inc. of Louisville, Ky. have provided plasma treated Viton O-ring seals which have been used with sample inlet assemblies as described above with the desired results.