HPVA – 100 High Pressure Volumentric Analyzer

Particulate Systems
The HPVA instruments are designed to measure the high-pressure adsorption isotherms with hydrogen, methane, carbon dioxide and other gases using the static volumetric method. Typical applications for this instrument include catalysts, zeolites, activated carbons, carbon nanotubes, and hydrides. Understanding the adsorption characteristics of materials is critical in the research and advancement of hydrogen storage, fuel cells and batteries stack gas scrubbers, and hydrocarbon traps.

The HPVA product operating pressure ranges from high vacuum to 200 bars. The span of the sample temperature during analysis can be from cryogenic to 500 oC. Sample analysis data collection is fully automated to assure quality data and high reproducibility.

Now available with 4 ports –
HPVA 4 Port Series Instrument Flyer

 

Characterizations for:

  • Catalysts
  • Zeolites
  • Activated Carbons
  • Carbon Nanotubes
  • Hydrides
   Materials for:

  • Hydrogen and NG Storage
  • Fuel cells and batteries
  • Stack gas scrubbers
  • Hydrocarbon traps

Features:

  • Pressure Ranges from ultra-high vacuum to 200 bars.
  • Temperatures from cryogenic to 500 °C. Excellent control of sample temperature by means of a constant temperature bath.
  • Fully automated analysis and sample evacuation.
  • Excellent data reproducibility.
  • Handles typical adsorbates such as Nitrogen, Hydrogen, Methane, Argon, Oxygen, Carbon Monoxide, and Carbon Dioxide.
  • Comprehensive Data Analysis Package using Microsoft® Excel® macros for data processing and graphing.
  • Software includes NIST RefProp Database 23.

Technique:

The volumetric technique consists of introducing (dosing) a known amount of gas (adsorptive) into the chamber containing the sample to be analyzed. When the sample reaches equilibrium with the adsorbate gas, the final equilibrium pressure is recorded. These data are then used to calculate the quantity of gas adsorbed by the sample. This process is repeated at given pressure intervals until the maximum preselected pressure is reached. Each of the resulting equilibrium points (volume adsorbed and equilibrium pressure) is then plotted to provide an isotherm. Excellent reproducibility and accuracy are obtained by using separate transducers for dosing the sample and for monitoring the pressure in the sample chamber.

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