Tubing and the fittings used to connect tubing to various HPLC system components are required for transporting the mobile phase and sample through the chromato-graph.. 3.4.1.2 High-Pressu
Trang 1of tubing wall in Fig 3.6b) With properly designed systems, sub-milliliter volumes
of tubing can be used for each solvent, with degassing effectiveness equivalent
to extended vacuum degassing under static conditions for most HPLC operations [5] Although not quite as effective as helium sparging, for most users the con-venience of in-line vacuum degassing and the cost of helium have made this the preferred degassing technique in place of helium sparging For applications where dissolved-oxygen concentrations are critical (e.g., some fluorescence and electro-chemical detection methods) or where extremely low and constant concentrations
of dissolved gases must be maintained (e.g., maximum sensitivity refractive-index detection), continuous helium sparging followed by in-line vacuum degassing is the best choice [5]
Tubing and the fittings used to connect tubing to various HPLC system components are required for transporting the mobile phase and sample through the chromato-graph If reasonable care is taken in the selection and use of tubing and fittings, problems will seldom be encountered However, improper selection and use can generate unwanted extra-column volume (Section 3.9), which can compromise the separation—especially for small peak volumes Additional technical information
on tubing and fittings can be found on the Internet [6–7] and in manufacturer’s literature, such as [8] Note that the following discussion refers to the dimensions and thread sizes of tubing and fittings in English units (usually fractional or decimal inches), because this is the way they are commonly supplied in the United States These products are available in metric sizes in many other markets As a note of caution, if both English and metric versions of similar products are used, be sure
to label them clearly—even if they may seem to fit together in some cases, since
damage to the part or a leak may result
3.4.1 Tubing
3.4.1.1 Low-Pressure Tubing
For pressures less than ≈100 psi, polymeric tubing generally is suitable The two primary applications are transport of the mobile phase from the reservoir to the pump, and waste from the detector to the waste container
On the inlet side of the pump, tubing generally is 1/8-in o.d and 1/16-in or smaller i.d The inertness of fluorocarbon tubing (e.g., Teflon®) makes it the first choice for transport of solvents to the pump Other polymers (e.g., polypropylene and polyethylene) may be suitable as well, but these products are best purchased from an HPLC supplies vendor to ensure that they are of sufficient purity for the application Teflon tubing is somewhat permeable to gas, so air can diffuse through the inlet tubing into the mobile phase Generally, air is not a problem, but in some applications (e.g., reductive electrochemical applications) dissolved oxygen in the mobile phase can cause problems PEEK (polyetheretherketone) tubing is another suitable inlet-line tubing; it is not gas-permeable but it is opaque, so it is not possible
to see bubbles inside the tubing PEEK tubing also has some limitations in terms of chemical compatibility (Section 3.4.1.2)
Trang 2On the waste side of the detector, Teflon, polypropylene, polyethylene, PEEK,
or other relatively inert tubing can be used For ease of connection with the detector outlet, 1/16-in o.d tubing generally is used as a waste line The use of tubing with an internal diameter of 0.010-in i.d or less will create sufficient back-pressure to keep bubbles in solution until they exit the detector cell—this will help reduce bubble problems in the detector However, with this technique, one should be careful not to overpressure the detector cell, especially if the flow rate is increased dramatically It usually is more prudent to use larger i.d tubing (e.g.,≥0.20-in) and a back-pressure
restrictor (available from many HPLC fittings suppliers) at the outlet end of the tubing to maintain 50 to 75 psi back-pressure at any flow rate
The length of tubing is not critical in low-pressure applications, but it is a good idea to keep these lengths to a convenient minimum Excessive tubing lengths can result in longer washout times and delayed equilibration Most low-pressure tubing
is cut with a razor blade or, for PEEK, a cutter supplied by the tubing vendor A flat cut, perpendicular to the tube axis is desired
3.4.1.2 High-Pressure Tubing
Whereas low-pressure tubing is used primarily to transport mobile phase to the pump or waste from the detector, high-pressure tubing is required elsewhere in the system Conventional HPLC systems are designed for use with pressures up to
6000 psi between the pump and detector, so the tubing must be able to withstand such pressures Also tubing used to transport the sample from the autosampler to the column and from the column to the detector must be sufficiently inert that sample adsorption or degradation does not take place, and the tubing length and diameter should be selected so that it does not contribute significantly to peak broadening (Section 3.9) Both stainless steel and PEEK tubing will satisfy these requirements for most applications
Type 316 stainless-steel tubing is most commonly used for HPLC applications
It is inert to nearly all solvents and has a very high burst strength It is less convenient
to use than PEEK tubing because of its stiffness PEEK tubing≤0.030-in i.d will work
up to pressures of≈7000 psi without rupturing; for higher pressures, stainless-steel tubing is required PEEK tubing is compatible with most HPLC mobile phases, but it will swell and become brittle when exposed to THF, chlorinated solvents, or DMSO (see [6 or 7] for a full listing of solvent compatibility) It is best to avoid PEEK when these solvents are present The convenience and flexibility of PEEK tubing make
it a good choice for use when connections are changed regularly, such as between the autosampler and column, and column and detector Whenever the mobile phase contains components corrosive to stainless steel, the use of PEEK tubing will help minimize problems When connections are made once and then forgotten, such as between the pump and autosampler, stainless-steel tubing is a more trouble-free choice
Tubing with an outside diameter of 1/16-in is used in most HPLC equipment; for some applications, 1/32-in o.d tubing is preferred, but it is more fragile Typical internal diameters for 1/16-in o.d tubing are listed in Table 3.1 Stainless-steel tubing is readily available in sizes from 0.005-in to 0.046-in i.d., whereas PEEK covers the 0.0025-in to 0.040-in range The 0.010-in and 0.020-in i.d sizes are used to transport solvent from the pump to the autosampler, where extra volume
Trang 3Table 3.1
Internal Diameters for Common High-Pressure Tubing (1/16-in o.d)
Internal Diameter (in) Internal Diameter (mm)a Volume ( μL/cm)
aNominal value (calculated from inch dimensions).
bAvailable only in PEEK.
cAvailable only in stainless steel.
is not a concern, and these diameters are unlikely to become blocked In the tubing where sample is present—between the autosampler and the column, and between the column and detector—smaller i.d tubing (e.g.,≤0.007-in i.d.) is needed to avoid
excessive peak broadening Larger diameter tubing (≥0.030-in i.d.) is used primarily for construction of injector loops, because of the relatively large volume per unit length (Table 3.1)
Care should be taken to select the tubing length and diameter so as to minimize peak-broadening contributions Table 3.2 shows the impact of various combinations
of tubing length and diameter on peak broadening for several representative column configurations It can be seen that although 0.007-in i.d tubing is satisfactory for conventional columns of ≥100 × 4.6 mm with ≥3-μm particles, smaller columns
require smaller diameter tubing Applications that use sub-2-μm particles and/or long tubing runs (e.g., LC-MS) will require the use of 0.0025-in i.d tubing The smaller the tubing, the more prone it is to blockage from particulates that originate from the mobile phase, pump seal, valve-rotor wear, or sample Consequently special care must be taken to avoid blockage when using tubing of≤0.005-in i.d Remember
that the tubing lengths shown in Table 3.2 are the total of the autosampler-to-column plus column-to-detector connections Sometimes it is advantageous to use a short piece of 0.007-in i.d tubing between the autosampler and column, so as to minimize blockage problems, and to use≤0.005-in tubing between the column and detector,
to minimize peak broadening See Section 3.9 for an additional discussion of extra-column peak broadening
Because it is difficult to duplicate the quality of factory-cut tubing, it is best to buy precut lengths of stainless-steel tubing Precut tubing has the added advantage
of having been thoroughly cleaned and passivated, so it can be used without further treatment Bulk stainless-steel (type 316 is recommended) can be purchased for cutting to lengths that cannot be purchased precut Stainless-steel tubing can be cut easily with a tubing cutter purchased from the tubing supplier The tubing should be flushed with several milliliters of solvent prior to use (connect the up-stream end of
Trang 4Table 3.2
Guide to Tubing Length
Column Characteristics Maximum Length (cm) for 5%
Increase in Bandwidtha
∗ ≤ 10 cm.
aConditions for linear velocity = 2.5 mm/sec within the column (e.g., 2 mL/min for a 4.6-mm i.d column),
k= 1.
the tubing to the HPLC system and direct the outlet to waste), so as to remove any residual oils or particulate matter PEEK tubing can be cut easily in the laboratory,
so it usually is purchased in bulk For best results, a PEEK tubing cutter is used to score a line around the tubing, then the tubing is flexed to snap it; this gives a higher quality tube end than cutting all the way through the tubing
3.4.2 Fittings
3.4.2.1 Low-Pressure Fittings
These fittings are used to connect tubing when the pressure will not exceed≈100 psi The two most common fitting designs are shown in Figure 3.7 The flared-tubing
fitting (e.g., Cheminert®, Fig 3.7a) requires a special tool to flare the tube end.
A washer is used between the nut and the flared end to help secure the tubing in the fitting port These fittings require some skill to flare but are inexpensive and reliable, so they are popular with instrument manufacturers to reduce manufacturing costs An alternate design uses a ferrule to secure the tube end (e.g., Fingertight®,
Fig 3.7b) The ferrule is reversed from the normal orientation in high-pressure fittings (as in Fig 3.8a) so that the flat end contacts the bottom of the fitting port.
The nut contains an internal taper that matches the ferrule so that the ferrule is swaged onto the tubing when the nut is tightened This type of fitting is easy to assemble (the knurled nut is tightened with finger pressure), which has made it a popular alternative to the flared-tubing fitting The industry standard is to use 14-in nuts with 28 threads per inch (1/4-28); this way low-pressure fittings from different manufacturers are interchangeable
Trang 5knurled, finger-tightened nut
(b)
flat-bottom port
inverted ferrule
(a)
tubing
nut
(flared end)
(c)
union
tube end
inverted ferrule
internal taper
nut threads
in here
Figure3.7 Fittings for low-pressure applications (a) Cheminert® fitting, using a washer and flange for the seal; (b) Fingertight® fitting, using an inverted ferrule for the seal (c) Low-pressure connection of two tube ends with inverted ferrule of (b) in a union (nuts not shown for clarity) (a) Courtesy of VICI Valco Instruments Co Inc.; (b) courtesy of Upchurch
Scientific, Inc., a unit of IDEX Corporation in the IDEX Health & Science Group
Tubing connections for low-pressure fittings are made as shown in Figure 3.7c.
Here two tube ends with inverted-ferrule fittings are connected in a union; the two ferrules butt against each other to make the connection (compare this to
the high-pressure union of Fig 3.8b,c) In other applications (e.g., a
solvent-proportioning manifold, Section 3.5.2.2) a flat-bottomed fitting port is formed in
the mating piece, as shown in the partially assembled fitting of Figure 3.7b.
Finger pressure is all that is needed to tighten low-pressure fittings, so it is recommended that all such fittings be finger tightened, even if the nut is designed for use with a wrench When a wrench or pair of pliers is used to tighten the fitting, it is easy to overtighten the fitting, and distort it or damage the threads For applications where the fitting might vibrate loose (e.g., on the solvent-proportioning manifold in low-pressure mixing systems), some manufacturers offer a lock nut
to provide extra security for low-pressure fittings Remember, in a low-pressure application sometimes a loose fitting will allow air to leak into the liquid stream without liquid leaking out, so a loose fitting does not necessarily create a puddle of mobile phase
Trang 6(a) (b)
(c)
(d )
tube end
knurled,finger-tightened nut
Figure3.8 Compression fittings for high-pressure tubing connections (a) Conventional stainless-steel nut, ferrule, and tube end; (b) union body; (c) properly assembled union (d)
Finger-tightened PEEK nut, ferrule, and fitting port Courtesy of Upchurch Scientific, Inc., a unit of IDEX Corporation in the IDEX Health & Science Group
3.4.2.2 High-Pressure Fittings
All high-pressure tubing connections are made with fittings that use a ferrule to
secure the tube end (Fig 3.8a) in the fitting port (Fig 3.8b) The fitting body,
whether it is a union, check valve, or other fitting, contains a threaded portion for the nut, a taper for the ferrule, and a cylindrical port where the tube end contacts the fitting To assemble the fitting, the nut and ferrule are slipped over the tube end, the tube end is inserted into the fitting until it bottoms out in the port, and then the nut is tightened to secure the fitting When the nut is tightened, compression between the nut and the taper in the fitting body swages (crimps) the ferrule onto the tubing and provides a secure connection When properly assembled, high-pressure fittings should have no gaps and little or no diameter change between the tubing
and the fitting body (Fig 3.8c) Such connections are referred to as zero-volume or zero-dead-volume connections.
Nearly all manufacturers standardize on nuts with 10-32 threads and use the same ferrule taper for fittings used with 1/16-in o.d tubing (different standards are used for metric sizes) This means that fittings from different manufacturers are nominally interchangeable However, different manufacturers’ fittings may have different port depths, which means that for stainless-steel fittings, where the ferrule
is tightly swaged onto the tubing, the ferrule setback from the end of the tube
(Fig 3.9a) may vary between manufacturers For example, Rheodyne injection
Trang 7(b)
ferrule setback
leaks
void volume
Figure3.9 Effect of ferrule setback on compression fitting assembly (a) Tube end showing ferrule setback; (b) assembly with (left) too large of a ferrule setback, causing leaks, or (right)
too small of a ferrule setback, creating a void volume
valves have noticeably deeper ports than most other fitting designs Mismatching
of the tube end and the fitting body after the fitting has been initially assembled can lead to problems, as illustrated in Figure 3.9b For the example with the large
ferrule setback, the tube end will reach the bottom of the fitting port before the
ferrule contacts its mating taper (left-hand side of Fig 3.9b) This will result in
a fitting that leaks Usually the ferrule can be forced to slide down the tubing as the nut is tightened; in this case the leak may stop and the fitting will be properly assembled When the tube end is moved back to its original fitting body, however, the ferrule will contact the fitting taper before the tube end bottoms out in the fitting
port (right-hand side of Fig 3.9b) This will result in a leak-free connection that
has a small void volume at the tube end, which can cause band spreading To avoid these problems, it is a good idea to stay with a single manufacturer’s fittings when stainless-steel fittings are used
High-pressure fittings are made of PEEK as well as stainless steel When the ferrule is made of PEEK (or some other polymer), it is not permanently swaged onto the tube end so that the ferrule can be slid easily into the proper position when a tube end is moved from one fitting to another An added convenience that is
popular in this fitting design is the use of a knurled PEEK nut (Fig 3.8d) that can be
finger-tightened instead of requiring a wrench Finger-tightened PEEK fittings can
be used for high-pressure fittings in conventional HPLC systems where pressures of
6000 psi are not exceeded For higher pressure applications, stainless-steel fittings are required If a PEEK fitting leaks, it is a good idea to turn off the pump, loosen the fitting, push the tubing to the bottom of the fitting port, and retighten the nut before turning the pump on again This will reduce the risk of having the tubing slip
during tightening, leaving a gap, as in Figure 3.9b.
Nuts, ferrules, and fitting bodies can be made of PEEK or stainless steel It is common to use PEEK nuts and ferrules in stainless stainless-steel fitting bodies, but stainless-steel nuts are rarely used with PEEK parts
Trang 8frit
out
(a)
(b)
Figure3.10 Specialty fittings (a) In-line filter showing filter body, nut, and replaceable frit (b) PEEK low-volume tee-mixer Images courtesy of Upchurch Scientific, Inc., a unit of IDEX
Corporation in the IDEX Health & Science Group
3.4.2.3 Specialty Fittings
Two modifications of standard high-pressure fittings provide special benefits:
• in-line filters
• low-volume mixers
The in-line filter (Fig 3.10a) is a modification of the standard union that is used
to connect two pieces of tubing A small-porosity frit (typically 0.5 μm porosity)
is used in the in-line filter to remove unwanted debris from the fluid stream It
is a good practice to use an in-line filter just downstream from the autosampler
on every HPLC system This adds an insignificant amount of extra-column peak broadening, yet prevents particulate matter from the mobile phase, pump seals, valve rotors, or samples from reaching the column inlet frit (Some pumps have built-in small-porosity filters at the pump outlet These serve to trap particulate matter from pump seals or other upstream sources In the absence of such filters, some users install an in-line filter between the pump and autosampler to prevent particulate matter from causing problems in the autosampler The column frit can seldom be changed without damage to the column, whereas the in-line frit is designed for easy replacement When the in-line filter becomes blocked, as signaled by an increase
in system pressure, the frit is replaced and the HPLC system is back in service
Trang 9with minimal downtime In-line filters are available from many vendors in either stainless-steel or PEEK construction, and with various frit porosities
A low-volume mixer can be used to convert high-pressure-mixing pumps
(Section 3.5.2) used for conventional applications to LC-MS-compatible pumps Typical high-pressure mixers have volumes of 1 mL or more, whereas low-volume static mixers often contain<10 μL of volume The example shown in Figure 3.10b
is made of PEEK and contains a 10-μm porosity frit to aid mixing, yet has only
2.2 μL of swept volume Other designs of low-volume mixers are also available.
Nearly all HPLC pumping systems in service today use some variation of the reciprocating-piston pump Hydraulic-amplifier pumps are used primarily for col-umn packing and also may be used for preparative applications (Section 15.2) Syringe pumps are used as infusion pumps for tuning LC-MS systems, but not for high-pressure solvent delivery Piston-diaphragm pumps that were once used for HPLC systems are no longer popular Reciprocating-piston pumps have evolved over the years into reliable units that can provide hundreds of hours of trouble-free operation without maintenance The precision and accuracy of the pump and its associated mobile-phase mixing system are keys to the success of HPLC as an analytical tool
Most HPLC pumping systems sold for routine analytical work are designed
to work at pressures of up to 6000 psi (400 bar), but most workers operate such systems in the 2000 to 3000 psi (150–200 bar) region HPLC systems that are promoted for fast analyses or high-pressure work, especially with sub-2-μm particle columns, have higher upper-pressure limits and may allow routine operation in the 8000 to 15,000 psi (550– 1000 bar) range or higher It should be noted that conventional systems operated in the 5000 to 6000 psi region are able to provide some of the benefits of faster runs with smaller particle columns, without the need
to purchase specialized equipment However, when conventional HPLC systems are used at higher pressures (e.g.,>3000 psi), care must be taken to prevent leaks For
example, injection-valve rotors may need to be tensioned for higher pressures and fittings may need to be tightened more Also, the mechanical wear rate of pump seals, injection rotor-seals, and other moving parts usually increases as the system operating pressure is increased
3.5.1 Reciprocating-Piston Pumps
The single-piston pump shown in Figure 3.11 is the core of all other HPLC pumping systems The main components are:
• motor
• piston
• pump seal
• check valves
The rotation of the pump motor (driving cam) drives the piston back and forth
in the pump head The piston usually is made of sapphire, although some pumps
Trang 10Intake Cycle
outlet check valve
piston
driving cam (motor)
inlet check valve
Delivery Cycle
pump seal
piston
(b) (a)
Figure3.11 Single-piston reciprocating pump (a) Intake (fill) cycle, (b) delivery cycle.
use ceramic pistons A polymeric pump seal is used to prevent mobile phase from leaking out of the pump head An inlet and outlet check valve control the direction
of flow of the mobile phase During the fill cycle (Fig 3.11a), the piston is pulled
out of the pump head, which creates a low-pressure region in the pump head The outlet check valve closes and the inlet check valve opens, which allows the mobile
phase to enter the pump During the delivery cycle (Fig 3.11b), the piston moves
into the pump head, the inlet check valve closes, and the outlet check valve opens, which allows mobile phase to flow to the column
A dependable check valve is important for reliable pump operation Ball-type
check valves are commonly used, as illustrated in Figure 3.12a The valve comprises
a ruby ball and sapphire seat This combination of materials gives a reliable seal, usually with no assistance other than gravity plus the pressure differential in the