A method for producing a blown and stripped biorenewable oil is provided. The method may include the steps of (a) heating a biorenewable oil to at least 90° C.; (b) exposing an oxygen containing stream to the heated oil to produce a blown oil having a viscosity of at least 40 cSt at 40° C.; (c) adding a base metal catalyst to the blown oil; and (d) stripping the blown oil from step (c) until the stripped oil has an acid value of from about 1 mg KOH/g to about 20 mg KOH/g; wherein the stripped oil from step (d) has a flash point of at least 220° C.

A method for producing a blown and stripped biorenewable oil is provided. The method may include the steps of (a) heating a biorenewable oil to at least 90° C.; (b) exposing an oxygen containing stream to the heated oil to produce a blown oil having a viscosity of at least 40 cSt at 40° C.; (c) adding a base metal catalyst to the blown oil; and (d) stripping the blown oil from step (c) until the stripped oil has an acid value of from about 1 mg KOH/g to about 20 mg KOH/g; wherein the stripped oil from step (d) has a flash point of at least 220° C.

The present disclosure relates to methods and systems for refining grain oil compositions using an esterase enzyme component, water, bleaching processes, and combinations thereof, and related compositions produced therefrom having one or more reduced color values. The present disclosure also relates to methods of using said compositions, e.g., as mineral oil replacements.

A vegetable oil physical refining process able to mitigate the occurrence of glycidyl esters (GE) including at least a deodorization step followed by a stripping step, wherein, the deodorization step includes contacting said vegetable oil with steam at a pressure above 5 mbara, during at least 10 minutes at a temperature of at least 230° C., and wherein the stripping step includes stripping the oil resulting from the deodorization step at a pressure below 5 mbara and at a temperature not exceeding 280° C. The process does not compromise the heat bleaching and the full removal of unwanted colours, taste and smell from the physically refined edible oil.

A vegetable oil physical refining process able to mitigate the occurrence of glycidyl esters (GE) including at least a deodorization step followed by a stripping step, wherein, the deodorization step includes contacting said vegetable oil with steam at a pressure above 5 mbara, during at least 10 minutes at a temperature of at least 230° C., and wherein the stripping step includes stripping the oil resulting from the deodorization step at a pressure below 5 mbara and at a temperature not exceeding 280° C. The process does not compromise the heat bleaching and the full removal of unwanted colours, taste and smell from the physically refined edible oil.

A process for manufacturing a refined vegetable oil having a reduced content of 3-MCPD esters characterized in that it comprises the following steps: treating a deodorized vegetable oil with a base in a continuous pipe reactor, and contacting the base treated oil with an adsorbent and/or an acid. The thus obtained oil is low in 3-MCPD and has a low degree of interesterification and a low DAK content. It further relates to the use a continuous pipe reactor for treating a deodorized vegetable oil with a base wherein 3-MCPD ester content is reduced in the oil.

A method to produce crude tall oil (CTO) having a reduced sulfur content is disclosed. Black liquor soap (BLS) is treated with 0.05 to 0.45% by weight H.sub.2O.sub.2. Hydrogen peroxide treated BLS compositions, CTO compositions, and chemical compositions derived thereof, including depitched CTO, TOP, depitched CTO distillation fractions, and products derived therefrom are disclosed. The use of a small amount of H.sub.2O.sub.2 results in a decreased degree of foaming.

A method to produce crude tall oil (CTO) having a reduced sulfur content is disclosed. Black liquor soap (BLS) is treated with 0.05 to 0.45% by weight H.sub.2O.sub.2. Hydrogen peroxide treated BLS compositions, CTO compositions, and chemical compositions derived thereof, including depitched CTO, TOP, depitched CTO distillation fractions, and products derived therefrom are disclosed. The use of a small amount of H.sub.2O.sub.2 results in a decreased degree of foaming.

The present invention relates to a method for reducing an amount of dissolved impurities in an oxygen containing renewable feedstock, the dissolved impurities being selected from impurities comprising phosphorus and impurities comprising at least one metal. The method comprises obtaining a net elementary charge of a first feedstock; mixing the first feedstock with an elementary charge balancing component to obtain the feedstock to be treated, whereby the feedstock to be treated has a net elementary charge which is closer to zero net elementary charge than the net elementary charge of the first feedstock; and subjecting the feedstock to be treated to a heat treatment at a temperature of 180-400° C. in order to precipitate compounds containing said phosphorus and said at least one metal.

The present invention relates to a method for reducing an amount of dissolved impurities in an oxygen containing renewable feedstock, the dissolved impurities being selected from impurities comprising phosphorus and impurities comprising at least one metal. The method comprises obtaining a net elementary charge of a first feedstock; mixing the first feedstock with an elementary charge balancing component to obtain the feedstock to be treated, whereby the feedstock to be treated has a net elementary charge which is closer to zero net elementary charge than the net elementary charge of the first feedstock; and subjecting the feedstock to be treated to a heat treatment at a temperature of 180-400° C. in order to precipitate compounds containing said phosphorus and said at least one metal.