Thar Technologies

Supercritical Fluid Extraction SFE

Supercritical fluid extraction processing shows numerous advantages when compared to traditional
organic solvent extraction. In traditional extraction, for example,
the residual solvent is unavoidable. In supercritical fluid
extraction, however, there is no residual solvent in the final
product. This translates into lower operating costs because of the
reduction in post–processing steps, clean–up and safety
measurements. Additionally, because CO2
processing requires low temperatures, there is less deterioration of
heat sensitive components in the extract. Furthermore, since there is
no oxygen in the process, the potential for oxidation of the extract
is significantly minimized.

Thar
Instruments is a designer, developer, and manufacturer of
solvent–free pilot ⁄
lab–scale supercritical fluid extraction systems. The
laboratory supercritical fluid extraction (SFE) system scale models
start from 100 mL up to 10 L. Models can include co–solvent pump,
fractionation and recycling.

More on SFE…

SFE
applications in the food and pharmaceutical industries:

• Decaffeinating
  of coffee and tea

• Extraction
  of essential oils (vegetable and fish oils)

• Extraction
  of flavors from natural resources (nutraceuticals)

• Extraction
  of ingredients from spices and red peppers

• Extraction
  of fat from food products

• Fractionation
  of polymeric materials

• Extraction
  from natural products

• Photo–resist
  cleaning

• Precision
  part cleaning

Supercritical Fluid Particle Designs SAS and RESS

Supercritical Anti Solvents: SAS

Rapid Expansion of Supercritical Solutions: RESS

Supercritical Fluid Reaction

Supercritical
fluid reaction is a reaction process using a supercritical fluid as a
solvent. When a fluid is taken above a particular temperature and
pressure (critical point of the respective fluid), it exists in a
condition called the supercritical fluid state. The physio–chemical
properties of a fluid in the supercritical state are in between those
of a typical gas and liquid. For example, the density of a
supercritical fluid can be changed by varying the pressure on the
fluid. As a result, a supercritical fluid can have a density that
ranges between those exhibited by gases to liquid–like values when
the fluid is compressed at high pressures. Carbon dioxide is
certainly the most popular fluid because of its physiological
compatibility, non–toxicity, inflammability, easy availability,
convenient critical parameters (Tc= 31° Celsius, Pc=7.38 MPa),
inexpensiveness and environmental friendliness.

The
Supercritical
Fluid Reaction
(SFR) systems are built to enable the user to rapidly react multiple
compounds with supercritical CO2,
and extract materials of interest. The user can operate in a static,
pressure control mode or a dynamic flow control mode. Thar produces
off–the–shelf, automated SFR⁄
Supercritical Fluid Extraction (SFE) kits for use in pharmaceutical,
chemical and food research laboratories.

Supercritical
Fluid Reaction Systems applications:

• Chemical
  reactions

• Polymerization

• Catalysis

• Oxidations

• Hydrogenations
  

Supercritical Phase Monitor 20 (SPM20)

Thar
Instruments´ Supercritical Phase Monitor is an important tool for
observing phase behavior and solubility of materials under pressure,
temperature, and sample concentration conditions. The equipment
features a variable volume viewcell body with a piston. The high
pressure motor–driven mixer allows the user to achieve high
stirring rates in the viewcell. The CCD camera and illumination
source, with two sapphire windows mounted 90° apart in the body,
provide the capability to view inside the viewcell. For temperature
control, the viewcell body is uniformly heated using embedded
heaters. Additionally, a simple lever–operated mechanism and a
precision valve enable the user to increase and decrease the
pressure, respectively, in the viewcell. A unique stand assembly
allows viewcell rotation up to 180° that allows inversion and
viewing of different phases (if present).

SPM20
Applications:

• Material
  solubility

• Solvents
  and CO2
  phase behavior

• Solubility
  studies for particle design

• Polymer
  swelling under pressure

• Chromatography
  optimization

• Reaction
  conditions

• Crystalization
  of compounds