The present invention provides a dynamic interface system between an extraction device and a chromatographic purification device for separating and purifying substance(s) from a mixture or matrix. One embodiment is the Supercritical Fluid Interface (SFI) between Supercritical Fluid Extraction (SFE), and Supercritical Fluid Chromatography (SFC). The SFI is capable of interfacing; gas, subcritical and supercritical fluid extraction methods and pair with gas, subcritical and supercritical fluid chromatography technologies that operate within the pressure and temperature parameters of the SFI. The SFI can operate up to 200 degrees celsius and 5000 psi. This interface technology allows for an inline oil extraction and chromatographic separation, the SFI can pair extraction and chromatography with the same solvent in different mobile phases, whereas the extraction can be performed using CO.sub.2 as a solvent in sub-critical phase and the SFI can receive the subcritical solution and then increase pressure and/or temperature to achieve supercritical state as required for injection into supercritical fluid chromatography technologies. The SFI coupling between SFE and SFC can to extract and refine cannabinoids from the cannabis industrious, hemp, plant and can also be applied to improve efficiency in an industry that extracts and refines oils, through chromatography, from organic materials using a gas, or sub/supercritical fluid as a solvent and mobile phase.

An apparatus to clear and upgrade a quality of native or recovered compounds, paraffinic or naphthenic, and other hydrocarbons containing compounds or polar species, which are to be separated and to adsorb components responsible for dark appearance or darkening of recycling motor oil, vegetable and animal fatty acids through of porous silica obtained from agricultural waste, including a treatment with adsorbent, a porous silica obtained from agricultural waste; one or more containers with different volumes and geometric shape, according to needs of what is going to be treated, configured for the porous silica, the hydrocarbons and other compounds to be treated in contact; an element for temperature control of the mixture of the silica with the compound to be treated; an element for controlling pressure and flow of the mixture of the silica with the compound; and an element that filters and retains the adsorbent inside of the apparatus.

Liquid chromatography techniques are disclosed. Specifically, the liquid chromatography technique includes providing a liquid chromatography system having a coated metallic fluid-contacting element, and transporting a fluid to contact the coated metallic fluid-contacting element. Conditions for the transporting of the fluid are selected from the group consisting of the temperature of the fluid being greater than 150 C., pressure urging the fluid being greater than 60 MPa, the fluid having a protein-containing analyte incompatible with one or both of titanium and polyether ether ketone, the fluid having a chelating agent incompatible with the one or both of the titanium or the polyether ether ketone, and combinations thereof.

Exemplary embodiments are directed to systems and methods used to minimize force variation from a solenoid through an operating stroke. The systems and methods generate a near constant or substantially constant force solenoid assembly which can be used in a force driven device, such as, for example, a pressure regulator for accurately controlling pressure in a pressurized flow system. The systems and methods are based on an initial solenoid characterization and include an application of springs and placement of the solenoid within the system at a gap distance to minimize variation in force in the operating stroke of a commercially available solenoid.

The present disclosure is directed at the selection and design of columns for liquid chromatography including liquid chromatography devices and systems and corresponding methods of operation, particularly in the field of high pressure liquid chromatography (HPLC).

A liquid chromatography having an on-line cleaning function, comprising a first flow channel (L3), a second flow channel (L21), an analysis flow channel (L22) and waste liquid flow channels, further comprising a cleaning flow channel (L25), a direction switch valve (V1) and a multi-flow channel switch valve (V2), etc. The liquid chromatography changes the flow path of the liquid by changing the communication relationship between the two-position switch valves, thus realizes the on-line cleaning function for a first chromatographic column (C1), a middle chromatographic column (C2), a filter or a protector (B2) respectively, and realize the simultaneous on-line cleaning function for the first chromatographic column (C1) and the middle chromatographic column (C2).

The technology generally relates to tailoring a back pressure regulator in a chromatographic system to reduce unswept volume within the back pressure regulator to achieve better sample detection and a reduction in chromatographic band distortion effects.

Exemplary embodiments of the present disclosure are directed to manipulating pressure-related hysteresis in a pressurized flow system by setting the pressure of the system to a predetermined location in the hysteresis band to advantageously minimize an effect of the pressure related hysteresis on the pressure of the system or to advantageously benefit from the effects of the hysteresis on the pressure of the system.

The present disclosure generally relates to systems, methods and devices for providing pressurized solvent flow in chromatography systems.

Thermally modulated variable restrictors used in chromatography systems enable independent control of system pressure and linear velocity of a compressible mobile phase passing through a chromatography column. A method for configuring a chromatography system with independent control of system pressure and mass flow rate of a compressible mobile phase includes determining a type of chromatography separation column to be used in the chromatography system, matching a thermally modulated variable restrictor to the type of chromatography separation column for use together during operation of the chromatography system, and bundling the chromatography column with its matching thermally modulated variable restrictor for distribution as a single package.