ULTRAFAST GC BRINGS SPEED, SPACE-SAVINGS, BETTER IT, EASIER USE, AND ENERGY SAVINGS TO THE LAB, THE PROCESS AND EVERYWHERE ELSE


With analytical cycles 10 to 50 times faster than traditional gas


chromatography, unltrafast GCs like the Calidus GC from Falcon Analytical vastly increase responsiveness for the data consumer. Less time spent waiting on results means more productivity and timely control of the measured process. In the hands of lab and process managers, the speed


of these GC analysers can translate into better quality products, produced faster and more profi tably than ever before.


The small analyser footprint allows for higher installation density in the laboratory and in shelters for process applications. This small footprint also enables process installation schemes that place the analyser much closer to its sampling point in the plant. Closer proximity means less sample lag time, as well as more representative measurements for process control.


Using modern computing with standard operating systems and software, the automated Falcon GC frees valuable technical resources from the daily grind of interpreting and validating chromatographic results. Built-in alignment software virtually eliminates misidentifi cation of components and drastically reduces the need for expensive calibration sample runs. Less time spent calibrating the analyser means more time spent on more economically valuable diagnostics, most notably measured process deviations from the setpoint.


Typical Calidus GC Chromatogram.


The patented, plug and play temperature-programmed gas chromatography column modules also allowed the Calidus GC designers to avoid the complicated and troublesome valve schemes used in isothermal process analysers and many lab gas chromatographs. Correlation between laboratory systems and online process control systems becomes realistically possible with this design, because both physical packages use the same measurement principle, hardware and methodology. Applying the design in-lab and online means less time spent reconciling lab and process measurements. More time can be spent working on more valuable, direct process optimisation.


The patented Calidus GC column module.


The Calidus Gas Chromatograph cycles 10 to 50 times faster than traditional GCs.


The Calidus GCs employ a patented direct, resistively heated column module. There is no need for an air bath oven in the design. Elimination of the air bath column ovens, that are required for traditional gas chromatography, drastically reduces the analyser’s footprint. At less than 11.5 kg and measuring 43 cm W X 21.5 cm D X 27.9 cm H, these GCs offer advanced analytical chemistry in a highly compact and transportable package.


The more obvious features and benefi ts outlined above combine to yield something that may not be that evident: Green Process Analytical Chemistry. Consuming less than 300 Watts in operation, the Falcon ultrafast GC uses a small fraction of the up to 3000-watt rate required by traditional gas chromatographs. Combine these savings with the reduction in workload for air conditioning systems


and the solution is greener still.


Ultrafast GCs also enable Green Process Analytical Chemistry. Applications The Ultrafast D7798 SimDis Method


Elimination of thermal bath ovens enables dramatic size reduction.


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