Exeter Analytical Inc. has written a white paper that discusses how CHN elemental analyzer design affects operational accuracy and precision, ease of use and handling of demanding sample types. The report examines the consequences of different commercial CHN elemental analyzer designs when the systems are run in real lab environments.
Data is provided showing the impact of horizontal versus vertical combustion systems. In a horizontal furnace arrangement the sample is introduced into the combustion tube on a quartz ladle, which critically enables the removal of all sample residues after combustion. In a vertical furnace arrangement the samples are combusted on top of previously combusted samples. This difference is a major factor contributing to the advantages of a static system with a horizontal furnace over both the dynamic and hybrid designs. The build up of sample residue in the combustion zone of vertical furnace systems is shown to considerably increase the potential for poor analytical data.
The most important criteria for CHN analysis in the majority of analytical laboratories is for optimal accuracy and precision across a wide range of sample types. With constant pressure to increase laboratory productivity an analyst does not want to set up their analyzer with different operational parameters for every different sample type they come across. Test data from an independent multi-laboratory study is included in the white paper demonstrating not only the superior accuracy and precision routinely achievable, but also how the inherently longer term stability with a horizontal furnace design markedly decreases time lost due to the need for recalibrations and sample re-runs.
Considerable variance in instrument performance can also be seen with more demanding samples. The advantages of a horizontal furnace design CHN elemental analyzer is illustrated with applications including time-dependent combustible samples and volatile liquids.
The report concludes that using a horizontal furnace design CHN elemental analyzer, such as the Exeter Analytical Model 440, allows analysts to routinely and simply produce accurate and precise data on wide ranging sample types without system re-optimization, saving precious time and reducing running costs.
For a copy of the white paper 'How instrument design affects CHN micro-analytical performance' please contact Exeter Analytical Inc. on tel. +1-978-251-1411 (+44-2476-323223 in Europe) or email sales@eai1.com (info@exeteranalytical.co.uk in Europe).
Data is provided showing the impact of horizontal versus vertical combustion systems. In a horizontal furnace arrangement the sample is introduced into the combustion tube on a quartz ladle, which critically enables the removal of all sample residues after combustion. In a vertical furnace arrangement the samples are combusted on top of previously combusted samples. This difference is a major factor contributing to the advantages of a static system with a horizontal furnace over both the dynamic and hybrid designs. The build up of sample residue in the combustion zone of vertical furnace systems is shown to considerably increase the potential for poor analytical data.
The most important criteria for CHN analysis in the majority of analytical laboratories is for optimal accuracy and precision across a wide range of sample types. With constant pressure to increase laboratory productivity an analyst does not want to set up their analyzer with different operational parameters for every different sample type they come across. Test data from an independent multi-laboratory study is included in the white paper demonstrating not only the superior accuracy and precision routinely achievable, but also how the inherently longer term stability with a horizontal furnace design markedly decreases time lost due to the need for recalibrations and sample re-runs.
Considerable variance in instrument performance can also be seen with more demanding samples. The advantages of a horizontal furnace design CHN elemental analyzer is illustrated with applications including time-dependent combustible samples and volatile liquids.
The report concludes that using a horizontal furnace design CHN elemental analyzer, such as the Exeter Analytical Model 440, allows analysts to routinely and simply produce accurate and precise data on wide ranging sample types without system re-optimization, saving precious time and reducing running costs.
For a copy of the white paper 'How instrument design affects CHN micro-analytical performance' please contact Exeter Analytical Inc. on tel. +1-978-251-1411 (+44-2476-323223 in Europe) or email sales@eai1.com (info@exeteranalytical.co.uk in Europe).
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