TITLE: Separation of Fischer-Tropsch wax from catalyst using supercritical fluid extraction. Quarterly technical progress report, July 1, 1995--September 31, 1995.

AUTHOR: M. C. Thies;   P. C. Joyce.

INST.  AUTHOR: Clemson Univ., SC. Dept. of Chemical Engineering.

SPONSOR: Department of Energy, Washington, DC.

LANGUAGE: English

PUB.  TYPE: Technical Report

PUB.  COUNTRY: United States

SOURCE: Department of Energy [DE],  1996,  8p.

NTIS ORDER NO.: DE96005859INW

ABSTRACT:

Programming and testing of the highly complex Statistical Associating Fluid Theory (or SAFT) equation of state is essentially complete. As an accuracy check, results from our program were compared and found to be in excellent agreement with those of two other research groups (one in the US and two in Europe) for both a nonassociating (methane-hexadecane) and an associating (carbon dioxide-methanol) system. This equation is being used to model the solubility our model Fischer-Tropsch compounds in supercritical solvents such as hexane. SAFT has been chosen for this work because of its fundamental rigor. Therefore, extension of our model compound results to the poorly defined Fischer-Tropsch waxes should be more successful compared to more empirical equations such as Peng-Robinson. Computer-controlled automation of one of our dynamic supercritical fluid (SCF) extraction apparatus is complete. The apparatus collects samples automatically, dramatically reducing operator manpower and fatigue, and is also capable of controlling the operating pressure more precisely (i.e., within (plus minus)2 psi). This apparatus (SFE I) will be used for future experiments with actual Fischer-Tropsch waxes.  Modification/construction of another apparatus (SCF II) that will be used for our model component-SCF phase equilibria/solubility studies is nearly complete; it is currently being leak-tested. This apparatus was built to handle the low mass flow rates that will be required when measuring solubility data for the more expensive model compounds, such as n-C40.  Anticipated results for the next quarter include VLE measurements for hexane-squalane at temperatures to 573 K.

REPORT  NUMBER: DOE/PC/94219-T4

CONTRACT  NUMBER: FG22-94PC94219