Agilent Quaternary Pump (e.g. G1311A ) "Secret" Operator Tip to FLUSH the HPLC Pump in 1/2 the time!

One of the most popular "tips" taught in our Agilent 1100 and 1200-series HPLC training classes shows users how to speed up the daily priming and flushing process of the Quaternary Pump. Many people use these pumps without taking advantage of the Quaternary pump's higher flow capability. If you are not currently using the higher 10mL/min flow rate capability offered by this pump (vs. the Binary pump's 5 mL/min), then you are missing out on a free time saving feature. Please read on to learn how to use this feature.

Based on the HP 1050 pump and introduced in 1995 as the "1100-series" version, the G1311  "Quat" pumps are one of the most popular research grade HPLC pumps found in laboratories today. They are extremely reliable, rugged, easy to operate and service. The Quat pump is driven by an easily accessible, single pump head with an in-series, servo controlled dual plunger and Multi-channel Gradient Valve ('MCGV') for 4-channel solvent proportioning with an active inlet valve (known as the 'AIV', first used in the HP 1050 pump and the reason for this pump's high reliability. No more "sticking" inlet valve issues!). Unlike the Agilent Binary pump (G1312), which uses two separate dual plunger pumps (2-channel) at up to 5.0 mL/min (maximum), the Quat pump offers an extended flow range, up to 10.0 mL/min (maximum). However, most users are not aware of this or do not know how to utilize this higher flow rate feature because the Quat pump defaults to a maximum flow rate of 5 mL/min at initialization. The ability to program the pump to operate at flow rates greater than 5 mL/min requires a "trick" to activate it (which apparently is a secret as we rarely encounter customers who are aware of how to use it). 

Let me share with you why you would want to use this feature, why the feature is hidden to most and of course HOW TO ACTIVATE IT on the Quat pump.

• Q: Why would you want to run the pump at 5 to 10 mL/min? Semi-prep columns can be run within this flow rate range, but a more common reason to operate at 10 mL/min is for daily system start-up. Anytime you replace or change the mobile phase bottle/solution OR when you startup the HPLC system (each day) one of the very first things you need to do is prime or flush each of the mobile phase channels, one-at-a-time through the system to waste. Air bleeds into the system when it is not used and this procedure primes the lines and pump head with fresh mobile phase preparing it for use. The system's flow path is directed to waste (via the open, prime-purge valve) during this step so back-pressure is not a concern. The higher the flow rate you can use for this flushing step, the sooner you can complete it. If you run the pump at 10 mL/min vs 5 mL/min, then flushing can be completed in half the time. This is especially useful if you have a model G1322A degasser module installed as the internal volume of each degassing channel in the G1322A is 10-12 mLs, requiring extended flushing times (4x channels = 30+ mLs flush per channel) before moving on to the next channel.

• Q: Why does the Quat pump initialize with a reduced, 5 mL/min maximum flow rate? The Quat pump was designed to meet two different operating pressure ranges. From 0 to 5 mL/min the permitted operating pressure range is 0 - 40 MPa (0 - 400 bar). Above 5 mL/min, the operating pressure range is reduced, 0 - 20 MPa (0 - 200 bar). As most analytical chromatography is performed at flow rates below 5 mL/min, the system initializes using the more practical, 0 - 400 bar range, limiting flow rates to 5 mL/min maximum. The default maximum pressure field is set to 400 bars. You should always change the maximum pressure value from 400 bars to a more realistic maximum pressure (lower value) for your method. Use a maximum value that is appropriate for your own method. *The only time you will want to set it to the maximum value is when conducting a Pump Pressure/Leak test (it must be set to max pressure for testing).
  

• Q: When I try and enter a pump flow rate larger than 5 mL/min, the system does not accept it. How do I program the pump to increase the flow rate past 5 mL to 10 mL/min? In order for the system to accept a flow rate of greater than 5 mL/min, you must FIRST set the maximum pressure limit to a value that is 200 bars or less (within the allowed "0 - 20 MPa (0 - 200 bar)" range). Once the maximum pressure limit has been reduced in the method, the system will then allow you to enter a higher flow rate such as 9.999 mL/min (10 mL/min). As long as the maximum pressure alarm is set within this window (200 or less), the pump will allow flow rates above 5 mL/min to be used. Now you can program the pump to flush lines or prime the system at twice the speed of the Binary pump equipped systems (10 mL/min).

Please share this "trick" with other users of the G1311A, G1311B, G1311C versions of this pump so they can maximize their time and productivity. Let us know if you find this tip useful.

HPLC Baseline Stabilization Tips for Refractive Index Detectors (RI or RID)

If you use refractive index detection (RID) for your HPLC samples, then you are already familiar with the very long equilibration periods needed to stabilize the system and associated baseline drift. Initial equilibration can take several hours. In fact, re-equilibration takes far longer to achieve with this detection mode than most others (i.e. UV/VIS, FLUOR, EC). While there is no quick cure for these delays, there are a number of things that you may be able to do to minimize or reduce these wait times. Here are a few to consider.

• ROOM TEMPERATURE: Locate the RID in a quiet, stable location. If the room temperature in which your HPLC system with RID system is located fluctuates by even one degree C, that can effect the stabilization of the system. The ideal room to use RID will be away from any windows, drafts, doorways, direct sunlight and HVAC vents or ducts. It should be located in a quiet area away from people walking by it. All of these things can contribute to temperature instability, which is what you want to avoid.

• INSULATION of HPLC CAPILLARY LINES: All of those stainless steel capillary lines leading from your column outlet to the RID's flow cell are loosing heat to the surrounding air (cooling). To reduce this thermal effect, insulate any metal lines with plastic tubing to reduce the heat loss. Most any type of laboratory grade, thick walled plastic tubing can be used. Pass the SS tubing through the plastic insulated tubing or use a section of split-tubing to cover it. Cover as much of the exposed tubing as possible, right up to the fittings. - Note: Sometime the HPLC system's solvent bottles may be subjected to varying temperature changes too. In these cases you can wrap the bottles with an appropriate insulating material to reduce the effects.

• FLOW CELL TEMPERATURE: Modern RID units have a heated flow cell with thermostat to control the temperature of the flow cell. This helps stabilize the temperature inside the flow cell as well as minimize the unintended effect that the heat given off by the RID's electronics has on the temperature inside the flow cell. If the flow cell temperature does not stabilize, then the baseline will drift in response to it. For most methods, select a flow cell temperature which is at least 10 degrees C above ambient (since most of these units can heat only, not cool). Factor in any column temperature used too. If you are maintaining your column at 40C, then try to maintain your flow cell at the same temperature to minimize any differences. Feel free to experiment to find the best temperature for your flow cell. Try different temperatures (in 5 degree C intervals), wait for the system to fully equilibrate, then measure the baseline S/N ratio. You may find best results using different column and flow cell temperatures. Sometimes the room temperature effect can be countered by using an optimized flow cell temperature (higher or lower). Always factor in your mobile phase boiling point (b.p.) into your method and keep the column and flow cell temperatures well below the b.p.

• DEGASSING / DECREASING DISSOLVED OXYGEN: Reduce and stabilize the amount of dissolved gas inside the mobile phase and you may achieve faster equilibration times with a RID. You do not need to remove all the dissolved gas (in fact, a reduction of 50% is often enough). The amount of dissolved gas inside the mobile phase effects the measured refractive index. As it changes, so does your baseline. High percentages of mobile phase dissolved gas = lower RI; Less dissolved gas = higher RI. Now water holds less dissolved gas than non-polar organic solvents (e.g. THF) so this effect is more pronounced when you are running non-aqueous GPC separations, but maintaining a stable dissolved gas level for all mobile phase types is important to reduce baseline drift. Stability is our goal. Continuous degassing of the mobile phase either through sparging with high purity helium gas (best for non-aqueous separations) OR using an inline vacuum degasser should provide you with a way to control the amount of dissolved gas in the solution and reduce drift.

These are a few of the factors which can effect the equilibration and drift times of an HPLC system equipped with a refractive index detector (RID). Careful selection of the instrument module's location, insulating the exposed capillary lines and bottles, optimizing the column and flow cell temperatures, maintaining a steady and controlled temperature in the environment, plus removing dissolved gas from the mobile phase may all contribute to more stable baselines and better quality peak integration. It is also a good idea to review training in the correct operation of the RI detector too. Learning to correctly operate the flush and optional recycle valves on these detectors is critical to their operation. Failure to properly flush the reference cell before each analysis with fresh mobile phase may lead to baseline changes or artifacts.

Another article which may help you improve your analysis method can be found on this site. "Diagnosing & Troubleshooting HPLC Pressure Fluctuation Problems (Unstable Baseline)".