This application claims the benefit of European Provisional Application No. 20190409.1, filed Aug. 11, 2020, which is incorporated by reference herein in its entirety.
The present invention relates to a novel process for reducing the content of MOSH and/or MOAH in vegetable lauric oils.
Mineral Oil Hydrocarbons (MOH) may be present as contaminants in oils and fat as well in foods prepared thereof. MOH are a complex mixture of molecules that are usually categorized into two main groups: Mineral Oil Saturated Hydrocarbons (MOSH) and Mineral Oil Aromatic Hydrocarbons (MOAH). MOSH are linear and branched alkanes and/or cycloalkanes. MOAH consists of highly alkylated mono- and/or polycyclic aromatic hydrocarbons.
Contamination of food and feed products with MOH may occur through migration from materials in contact with food such as plastic materials, like polypropylene or polyethylene, recycled cardboard and jute bags. Contamination also occurs from the use of mineral oil-based food additives or processing aids and from unintentional contamination like for example from lubricants or exhaust gases from combustion engines.
From a health perspective, it is desirable to reduce, or even completely remove, MOSH and MOAH contamination from edible vegetable oils.
Crude oils, as extracted from their original source, are not suitable for human consumption due the presence of impurities—such as free fatty acids, phosphatides, metals and pigments—which may be harmful or may cause an undesirable colour, odour or taste. Crude oils are therefore refined before use. The refining process typically consists of three major steps: degumming, bleaching and deodorizing. Optionally, a fourth step of chemical refining is included. An oil obtained after completion of the refining process (called a “refined oil” or more specifically a deodorized oil) is normally considered suitable for human consumption and may therefore be used in the production of any number of foods and beverages.
Unfortunately, existing refining processes are not effective to remove MOSH and/or MOAH. There is a need in the industry to identify an efficient and effective method for reducing MOSH and/or MOAH levels in vegetable oils. The present invention provides such a process.
The present invention relates to a process for reducing the content of MOSH and/or MOAH from a vegetable lauric oil, wherein the process is comprising the step of short-path evaporation of the vegetable lauric oil, wherein the short-path evaporation is performed at a pressure of below 1 mbar, at an evaporator temperature in a range of from 150 to 200° C. and with a feed rate per unit area of evaporator surface of the shorth-path evaporation equipment in a range of from 10 to 50 kg/h·m2, and thus obtaining a retentate vegetable lauric oil and a distillate.
The present invention further relates to the use of short-path evaporation for reducing the content of MOSH and/or MOAH from a vegetable lauric oil, wherein the short-path evaporation is performed at a pressure below 1 mbar, below 0.05 mbar, more preferably below 0.01 mbar, or even below 0.001 mbar.
The present invention relates to a process for reducing the content of MOSH and/or MOAH from a vegetable lauric oil, wherein the process is comprising the step of subjecting a vegetable lauric oil to a short-path evaporation, wherein the short-path evaporation is performed at a pressure of below 1 mbar, at an evaporator temperature in a range of from 150 to 200° C. and with a feed rate per unit area of evaporator surface of the shorth-path evaporation equipment in a range of from 10 to 50 kg/h·m2, and thus obtaining a retentate vegetable lauric oil and a distillate.
The term “vegetable lauric oil” is encompassing vegetable oils having a content of C6 to C12 fatty acids of more than 50%. Examples of such an oil include coconut oil, palm kernel oil, babassu oil, cohune oil, tacum oil and cuphea oil or any mixture of two or more thereof. For the purposes of the present invention, the vegetable lauric oil will preferably be coconut oil and/or palm kernel oil, most preferably coconut oil.
The vegetable lauric oil that is subjected to the short-path evaporation of the process of the invention may be derived from one or more vegetable sources and may include oils and/or fats from a single origin, or blends of two or more oils and/or fats from different sources or with different characteristics. The vegetable lauric oil may be occurring in nature and/or may have been subjected to a refining process, such as, but not limited to, degumming, bleaching, and/or deodorization. The vegetable lauric oil may be also be derived from oils and/or fats that have been subjected to a process for modifying the structure of the oils and/or fats, such as, but not limited to, fractionation, hydrogenation, interesterification or a combination two or more processes thereof.
The vegetable lauric oils have a molecular weight of less than 720 g/mol, less than 710 g/mol, less than 700 g/mol, or even less than 690 g/mol.
In one aspect of the invention, the vegetable lauric oil that is subjected to the short-path evaporation of the process is a degummed, bleached and/or deodorized vegetable lauric oil. Preferably the vegetable lauric oil is at least degummed.
Crude vegetable lauric oil may be subjected to one or more degumming steps. Any of a variety of degumming processes known in the art may be used. One such process (known as “water degumming”) includes mixing water with the oil and separating the resulting mixture into an oil component and an oil-insoluble hydrated phosphatides component, sometimes referred to as “wet gum” or “wet lecithin”. Alternatively, phosphatide content can be reduced (or further reduced) by other degumming processes, such as acid degumming (using citric or phosphoric acid for instance), enzymatic degumming (e.g., ENZYMAX from Lurgi) or chemical degumming (e.g., SUPERIUNI degumming from Unilever or TOP degumming from VandeMoortele/Dijkstra CS). Alternatively, phosphatide content can also be reduced (or further reduced) by means of acid conditioning, wherein the oil is treated with acid in a high shear mixer and is subsequently sent without any separation of the phosphatides to the bleaching step.
The bleaching step in general is a process step whereby impurities are removed to improve the color and flavor of the oil. It is typically performed prior to deodorization. The nature of the bleaching step will depend, at least in part, on the nature and quality of the oil being bleached. Generally, a crude or partially refined oil will be mixed with a bleaching agent which combines, amongst others, with oxidation products, phosphatides, trace soaps, pigments and other compounds to enable their removal. The nature of the bleaching agent can be selected to match the nature of the crude or partially refined oil to yield a desirable bleached oil. Bleaching agents generally include natural or “activated” bleaching clays, also referred to as “bleaching earths”, activated carbon and various silicates. Natural bleaching agent refers to non-activated bleaching agents. They occur in nature or they occur in nature and have been cleaned, dried, milled and/or packed ready for use. Activated bleaching agent refers to bleaching agents that have been chemically modified, for example by activation with acid or alkali, and/or bleaching agents that have been physically activated, for example by thermal treatment. Activation includes the increase of the surface in order to improve the bleaching efficiency. Further, bleaching clays may be characterized based on their pH value. Typically, acid-activated clays have a pH value of 2.0 to 5.0. Neutral clays have a pH value of 5.5 to 9.0. A skilled person will be able to select a suitable bleaching agent from those that are commercially available based on the oil being refined and the desired end use of that oil.
The bleaching step for obtaining the degummed and bleached vegetable lauric oil that is subjected to the short-path evaporation of the process, is performed at a temperature of from 80 to 115° C., from 85 to 110° C., or from 90 to 105° C., in presence of neutral and/or natural bleaching earth in an amount of from 0.2 to 5%, from 0.5 to 3%, or from 0.7 to 1.5% based on amount of oil.
Deodorization is a process whereby free fatty acids (FFAs) and other volatile impurities are removed by treating (or “stripping”) a crude or partially refined oil under vacuum and at elevated temperature with sparge steam, nitrogen or other gasses. The deodorization process and its many variations and manipulations are well known in the art and the deodorization step of the present invention may be based on a single variation or on multiple variations thereof.
For instance, deodorizers may be selected from any of a wide variety of commercially available systems (such as those sold by Krupp of Hamburg, Germany; De Smet Group, S.A. of Brussels, Belgium; Gianazza Technology s.r.l. of Legnano, Italy; Alfa Laval AB of Lund, Sweden Crown Ironworks of the United States, or others). The deodorizer may have several configurations, such as horizontal vessels or vertical tray-type deodorizers.
Deodorization is typically carried out at elevated temperatures and reduced pressure to better volatilize the FFAs and other impurities. The precise temperature and pressure may vary depending on the nature and quality of the oil being processed. The pressure, for instance, will preferably be no greater than 10 mm Hg but certain aspects of the invention may benefit from a pressure below or equal to 5 mm Hg, e.g. 1-4 mm Hg. The temperature in the deodorizer may be varied as desired to optimize the yield and quality of the deodorized oil. At higher temperatures, reactions which may degrade the quality of the oil will proceed more quickly. For example, at higher temperatures, cis-fatty acids may be converted into their less desirable trans form. Operating the deodorizer at lower temperatures may minimize the cis-to-trans conversion, but will generally take longer or require more stripping medium or lower pressure to remove the requisite percentage of volatile impurities. As such, deodorization is typically performed at a temperature of the oil in a range of 200 to 280° C., with temperatures of about 220-270° C. being useful for many oils. Typically, deodorization is thus occurring in a deodorizer whereby volatile components such as FFAs and other unwanted volatile components that may cause off-flavors in the oil, are removed. Deodorization may also result in the thermal degradation of unwanted components.
The deodorization step for obtaining the degummed, bleached and deodorized vegetable lauric oil that is subjected to the short-path evaporation of the process, is performed at a temperature of from 200° C. to 270° C., from 210° C. to 260° C., or from 220° C. to 250° C. The deodorization step is taking place for a period of time from 30 min to 240 min, from 45 min to 180 min, or from 60 min to 150 min.
The deodorization step for obtaining the degummed, bleached and deodorized vegetable lauric oil that is subjected to the short-path evaporation of the process, is performed in the presence of sparge steam in a range of from 0.50 to 2.50 wt %, from 0.75 to 2.00 wt %, from 1.00 to 1.75 wt %, or from1.25 to 1.50 wt % based on amount of oil, and at an absolute pressure of 10 mbar or less, 7 mbar or less, 5 mbar or less, 3 mbar or less, 2 mbar or less.
Typically, a degummed, bleached and deodorized vegetable edible oil is known to be obtained by means of 2 major types of refining processes, i.e. a chemical or a physical refining process. The chemical refining process may typically comprise the major steps of degumming, alkali refining, also called neutralization, bleaching and deodorizing. The thus obtained deodorized oil is a chemically refined oil, also called “NBD” oil. Alternatively, the physical refining process may typically comprise the major steps of degumming, bleaching and deodorizing. A physically refining process is not comprising an alkali neutralization step as is present in the chemical refining process. The thus obtained deodorized oil is a physically refined oil, also called “RBD” oil.
The vegetable lauric oil that is subjected to the short-path evaporation of the process is a degummed, bleached and deodorized vegetable lauric oil and a method for obtaining the degummed, bleached and deodorized vegetable lauric oil is comprising the steps of:
The vegetable lauric oil that is subjected to the short-path evaporation may have a content of MOSH of 20 ppm or higher, 40 ppm or higher, 60 ppm or higher, or even 80 ppm or higher. The content of MOAH may be more than 5 ppm or higher, more than 10 or higher, more than 20 ppm or higher, more than 40 ppm or higher, or even more than 60 ppm or higher.
Short-path evaporation, also called short-path distillation or molecular distillation, is a distillation technique that involves the distillate travelling a short distance, often only a few centimetres, and it is normally done at reduced pressure. With short path distillation, a decrease of boiling temperature is obtained by reducing the operating pressure. It is a continuous process with very short residence time. This technique is often used for compounds which are unstable at high temperatures or to purify small amounts of compounds. The advantage is that the heating temperature can be considerably lower (at reduced pressure) than the boiling point of the liquid at standard pressure. Additionally, short-path evaporation allows working at very low pressure.
Different types of short-path evaporation apparatus can be used that are well known to the skilled person. Examples are, but are not limited to, falling film, centrifugal, or wiped film evaporation apparatus. Preferably the short-path evaporation of the current process is performed in a wiped film evaporation apparatus.
The short-path evaporation is performed at a pressure below 1 mbar, preferably below 0.05 mbar, more preferably below 0.01 mbar, most preferably below 0.001 mbar.
The short-path evaporation is further performed at specific conditions of temperature and feed rate per unit area of evaporator surface of the shorth-path evaporation equipment.
The “feed rate per unit area of evaporator surface of the shorth-path evaporation equipment”, also called “specific throughput” or “specific feed rate”, expressed in kg/h·m2, is defined as the flow of oil, expressed in kg/h, per unit area of evaporator surface of the short-path evaporation equipment, expressed in m2. The feed rate per unit area of evaporator surface of the shorth-path evaporation equipment in the process of the current invention is applicable to any short path equipment, including industrial short-path evaporation equipment independent of the dimensions of the equipment. Preferably stainless steel short-path evaporation equipment is used in the current invention.
The short-path evaporation of the current process is performed at an evaporator temperature in a range of from 150 to 200° C., from 155 to 195° C., or from 160 to 190° C. and with a feed rate per unit area of evaporator surface of the shorth-path evaporation equipment in a range of from 10 to 50 kg/h·m2, from 15 to 45 kg/h·m2, or from 20 to 40 kg/h·m2.
In the process according to the invention, two fractions are obtained from the short-path evaporation: a retentate vegetable lauric oil and a distillate.
The process according to the invention results in a retentate vegetable lauric oil having a reduced content of MOSH and/or MOAH and a distillate having an elevated content of MOSH and/or MOAH, compared to the vegetable lauric oil that is subjected to the short-path evaporation.
Method DIN EN 16995:2017 (as part of CEN/TC275/WG 13) is the method that is used to measure the content of MOSH as well as the content of MOAH.
The “content of MOSH” is defined as the total amount of saturated hydrocarbons (MOSH) with a carbon chain length in a range of C10 to C50.
The “content of MOAH” is defined as the total amount of aromatic hydrocarbons (MOAH) with a carbon chain length in a range of C10 to C50.
The process according to the invention results in a retentate vegetable lauric oil having a reduction of MOSH and/or MOAH content in a range of from 25 to 60%, or from 30 to 55% while the yield of the retentate vegetable lauric oil is more than 60%, or more than 70%, more than 80%, more than 90%. The yield is expressed as the ratio of the amount of retentate vegetable liquid oil that is obtained versus the amount of vegetable liquid oil that was subjected to the short-path evaporation.
In a preferred aspect of the invention, the short-path evaporation of the current invention allows obtaining a reduction of MOSH and/or MOAH content of the retentate vegetable lauric oil may be obtained in a range of from 25 to 30%, while the yield is in a range of from 90 to 95%.
Additionally, the retentate vegetable lauric oil may have a reduced content of glycidyl esters (GE). GE are contaminants that are typically being formed as a result of the oils being exposed to high temperatures during oil processing, especially during deodorization. The GE content of the retentate vegetable lauric oil is below 1.0 ppm, below 0.8 ppm, below 0.5 ppm, below 0.3 ppm, below 0.1 ppm, or below LOQ (limit of quantification). The content of GE is measured with Method DGF Standard Methods Section C (Fats) C-VI 18(10).
In another aspect of the invention, the process is characterized in that it is comprising a further treatment with sparge steam of the retentate vegetable lauric oil obtained from the short-path evaporation.
The further treatment with sparge steam may be performed in equipment commonly known for treatment with sparge steam, such as, but not limited to, a deodorizer unit, a stripping unit, or a collection tray.
In one aspect of the invention, the further treatment with sparge steam is carried out at a temperature below 260° C., below 240° C., or below 220° C.
In another aspect of the invention, the further treatment with sparge steam is carried out in the presence of sparge steam in an amount of from 0.1 to 2.0 wt %, from 0.2 to 1.8 wt %, or from 0.3 to 1.5 wt %, based on amount of oil.
In one more aspect of the invention, the further treatment with sparge steam is carried out for a period of time of from 5 to 120 min, from 10 to 90 min, from 20 to 60 min, or from 30 to 45 min.
The further treatment with sparge steam in the present process may result in a further improvement of the flavour of the retentate vegetable lauric oil. The refined vegetable lauric oil after further treatment with sparge steam has an overall flavour quality score (taste), according to AOCS method Cg 2-83, in a range of from 7 to 10, or from 8 to 10 or from 9 to 10 (with 10 being an excellent overall flavour quality score and 1 being the worst score).
In one preferred aspect, the further treatment with sparge steam in the present process is carried out at a temperature below 220° C., below 210° C., or below 190° C., from 130 to 210° C., or from 150 to 185° C. This further refining at a temperature below 220° C. may result in a retentate vegetable lauric oil that is reduced in MOSH and/or MOAH, and that has a reduced content of GE, and that has a taste that is acceptable to good. The GE content of the retentate vegetable lauric oil is below 1 ppm, below 0.8 ppm, below 0.5 ppm, below 0.3 ppm, below 0.1 ppm, or below LOQ (limit of quantification). The retentate vegetable lauric oil after further treatment with sparge steam has an overall flavour quality score (taste), according to AOCS method Cg 2-83, in a range of from 7 to 10, or from 8 to 10 or from 9 to 10 (with 10 being an excellent overall flavour quality score and 1 being the worst score).
The present invention further relates to the use of short-path evaporation for reducing the content of MOSH and/or MOAH from a vegetable lauric oil, wherein the short-path evaporation is performed at a pressure below 1 mbar, below 0.05 mbar, more preferably below 0.01 mbar, or even below 0.001 mbar, and wherein a retentate vegetable lauric oil is obtained.
In one aspect, the current invention relates to the use wherein the short-path evaporation of the current invention is performed at an evaporator temperature in a range of from 150 to 200° C., from 155 to 195° C., from 160 to 190° C., or from 165 to 185° C., and at a feed rate per unit area of evaporator surface in a range of from 10 to 50 kg/h·m2, from 15 to 45 kg/h·m2, from 20 to 40 kg/h·m2or from 25 to 35 kg/h·m2, and whereby the vegetable lauric oil that is subjected to the short-path evaporation has a molecular weight of less than 720 g/mol, and wherein the content of MOSH and/or MOAH in the retentate vegetable lauric oil is reduced with 25 to 60%, or from 30 to 55%, and the yield of the retentate vegetable lauric oil is more than 60%, or more than 70%, more than 80%, more than 90%.
In one aspect, the current invention relates to the use of short-path evaporation followed by a further refining of the retentate vegetable lauric oil for reducing content of MOSH/MOAH and GE, wherein the short-path evaporation is performed at a pressure below 1 mbar, below 0.05 mbar, more preferably below 0.01 mbar, or even below 0.001 mbar, and wherein the further refining step is carried out in an oil refining equipment consisting of a stripping column with packing and not more than one oil collection tray or in a deodorizer, and at a temperature below 220° C., below 210° C., or below 190° C., from 130 to 210° C., or from 150 to 185° C., and wherein the GE content of the retentate vegetable lauric oil is below 1 ppm, below 0.8 ppm, below 0.5 ppm, below 0.3 ppm, below 0.1 ppm, or below LOQ (limit of quantification).
Refined, bleached and deodorized (RBD) coconut oil was spiked with 25 ppm of a master-mix based on lubricants, lube sprays and used engine oil containing MOSH-MOAH. Table 1 describes the composition of the MOAH-MOAH master-mix.
Short-Path Evaporation (SPE) Unit KDL-5 from UIC was used for the short-path evaporation. The KDL-5 unit has an evaporator surface of 0.048 m2
The following conditions were applied:
Conversion of applied feed rates in KDL-5 SPE Unit (in liter/hour) to feed rate in a KD-10 industrial SPE Unit from IUC (in kg/h), and further conversion to the feed rate per unit area of evaporator surface of the shorth-path evaporation equipment (in kg/h·m2) for industrial scale short-path evaporation equipment is shown in table 2.
Thus, the example is conducted according to the specifications of the claims.
MOSH and MOAH content of the oils was analyzed for the spiked RBD oils before the SPE treatment (=starting material of test) and after (=retentate of test). The yield of the retentate vegetable lauric oil was calculated based on the amount of retentate vegetable lauric oil after SPE treatment versus the amount of spiked RBD oil before the SPE treatment. The results are shown in Table 3.
Number | Date | Country | Kind |
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20190409.1 | Aug 2020 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/US2021/043445 | 7/28/2021 | WO |