The invention relates to method for deacidification of fats and oils comprising: feeding stream (1) to a stripping section; condensing the volatile phase in a high temperature condensing zone, sending the condensed phase to distillation A; distillating the condensed phase, obtaining a volatile stream; passing the volatile stream along with the vapor phase from the condensation zone to a cold condensation zone obtaining a condensate and a stream (4); allowing stream (4) to continue to vacuum system and subjecting the cold condensate to distillation B; and producing a stream of fatty acids (5) and a stream of micronutrients (6).

The invention relates to method for deacidification of fats and oils comprising: feeding stream (1) to a stripping section; condensing the volatile phase in a high temperature condensing zone, sending the condensed phase to distillation A; distillating the condensed phase, obtaining a volatile stream; passing the volatile stream along with the vapor phase from the condensation zone to a cold condensation zone obtaining a condensate and a stream (4); allowing stream (4) to continue to vacuum system and subjecting the cold condensate to distillation B; and producing a stream of fatty acids (5) and a stream of micronutrients (6).

Pitch production systems utilizing coal tar or decant oil for coal or petroleum based pitch are disclosed. Total pitch production yields are increased by heat treating distillate fractions from the pitch production process. A heat treatment system and process are disclosed in embodiments. The heaviest distillates having the highest molecular weights are subjected to heat treatment, though other embodiments contemplate heat treating a variety of combined distillate fractions. The heat treatment systems require heat soaking the distillate(s) at elevated temperatures of 459-535° C. at a near-constant temperature with near-uniform flow. A fraction of the heat-treated distillate may be reintroduced to the pitch production system as part of a continuous process.

Pitch production systems utilizing coal tar or decant oil for coal or petroleum based pitch are disclosed. Total pitch production yields are increased by heat treating distillate fractions from the pitch production process. A heat treatment system and process are disclosed in embodiments. The heaviest distillates having the highest molecular weights are subjected to heat treatment, though other embodiments contemplate heat treating a variety of combined distillate fractions. The heat treatment systems require heat soaking the distillate(s) at elevated temperatures of 459-535° C. at a near-constant temperature with near-uniform flow. A fraction of the heat-treated distillate may be reintroduced to the pitch production system as part of a continuous process.

Techniques recycle plastics in multiple successive process steps. A polymer, preferably a recyclable material, is melted using a discharge extruder, filtered using a first filter device under a positive pressure atmosphere, filtered and degassed using a degassing device, and discharged using a discharge extruder. The degassing device has at least one filter element and a vacuum chamber with a negative pressure atmosphere for filtering and degassing purposes, wherein the plastic melt can be conducted into the negative pressure atmosphere of the vacuum chamber through the filter element.

The invention relates to a method and a device for cleaning contaminated used oil, in which starting material is heated to the gas phase and the resultant vapor is rectified, with purified oil being removed as condensate from a drain in a rectification column. This enables efficient operation even in the smallest of systems, such that a compact system configuration and thus in particular mobile use by a container structure is made possible. The invention also reduces the cost required for servicing. The used oil is subjected to an evaporation process by at least indirectly placing the starting material in contact with a melting bath, the melting temperature of which is above the evaporation temperature but below the ignition temperature of the used oil, and by rectifying the vapor in the rectification column.

The invention relates to a method and a device for cleaning contaminated used oil, in which starting material is heated to the gas phase and the resultant vapor is rectified, with purified oil being removed as condensate from a drain in a rectification column. This enables efficient operation even in the smallest of systems, such that a compact system configuration and thus in particular mobile use by a container structure is made possible. The invention also reduces the cost required for servicing. The used oil is subjected to an evaporation process by at least indirectly placing the starting material in contact with a melting bath, the melting temperature of which is above the evaporation temperature but below the ignition temperature of the used oil, and by rectifying the vapor in the rectification column.

A sample concentrating unit and a sample concentrating method are described, which enable fast, precise and reproducible analyte concentration in a sample by evaporation of sample solvent. A specifically directed gas stream in cooperation with a vacuum generated in the sample concentrating unit keeps the sample at boiling point during the entire evaporation procedure while reducing analyte loss and risk of cross-contamination. The fully automated sample concentrating unit is designed to be integrated into an in-vitro diagnostic analyzer.

A process to produce aromatic compounds in a heavy oil product stream comprising the steps of separating the depressurized effluent to produce a vapor product stream and a liquid product stream, reducing a temperature of the vapor product stream to produce a cooled vapor product, separating the cooled vapor product to produce a light oil stream, wherein the light oil stream comprises olefins, separating the light oil stream to produce a light oil slip stream and a light stream, mixing the light stream with a water feed stream to produce an olefin-containing water stream, increasing a pressure of the olefin-containing water stream to produce a pressurized water feed, increasing a temperature of the pressurized water feed to produce a hot water feed, wherein a temperature of the hot water feed is greater than 450° C., converting olefins to aromatic compounds in the hot water feed.

A process to produce aromatic compounds in a heavy oil product stream comprising the steps of separating the depressurized effluent to produce a vapor product stream and a liquid product stream, reducing a temperature of the vapor product stream to produce a cooled vapor product, separating the cooled vapor product to produce a light oil stream, wherein the light oil stream comprises olefins, separating the light oil stream to produce a light oil slip stream and a light stream, mixing the light stream with a water feed stream to produce an olefin-containing water stream, increasing a pressure of the olefin-containing water stream to produce a pressurized water feed, increasing a temperature of the pressurized water feed to produce a hot water feed, wherein a temperature of the hot water feed is greater than 450° C., converting olefins to aromatic compounds in the hot water feed.