GB2091292A

GB2091292A - Separating Wax From Simmondsia Using Gas Under Supercritical Conditions

Info

Publication number: GB2091292A
Application number: GB8137117A
Authority: GB
Original assignee: Kali Chemie Pharma GmbH
Current assignee: Abbott Products GmbH
Priority date: 1981-01-15
Filing date: 1981-12-09
Publication date: 1982-07-28
Also published as: DE3101025A1; JPS57145195A; AU7951282A; DD201915A5; FI820074L; NZ199390A; GR75832B; ZA817997B; IL64587A0; BE891781A; PT74018A; FR2497823A1; NL8105301A; ES508714A0; SE8200069L; IT8125240A0; NO820104L; ES8306788A1; AT372608B; DK12982A

Abstract

Wax is extracted from seed kernels of species of Simmondsia by means of gas under supercritical conditions, separation of the wax being achieved by providing sub-critical conditions, the gas being returned into the extraction stage and the wax being removed. CO2 is the preferred gas.

Description

SPECIFICATION Process for the Separation of Valuable Matter from Plant Material This invention relates to a method for the separation of valuable substances from plant matter.

Forty-five to fifty percent by weight of the total weight of fully ripened seed kernels of plants of the species Simmondsia (simmondsia chinensis and simmonsia california) consist of a fluid wax.

This wax is a mixture of long-chain fatty acid esters, the acid component of which is formed from higher, straight chain acids and the alcohol component of which is formed from higher, monovalent alcohols. Thus it differs substantially from normal plant oils, which, as is known, are triglycerides of glycerol. Owing to its good stability it has a variety of uses, for example as a carrier or excipient for cosmetic or pharmaceutical formulations.

Methods used hitherto for the separation and isolation of the wax include cold or hot extrusion of the seed kernels, or the extraction of the wax with various solvents from the previously ground or compressed seed kernels.

Apart from the fact that with mechanical extrusion only approximately 60 to 70% of the wax content can be extracted, usual commercial qualities, which have been obtained by extrusion, still contain portions of cell matter. These portions of cell matter which are intrusive for many purposes, must be separated in further process steps. However, particular filtering methods, which use conventional filter media such as, for example, kieselguhr, silica gel, fuller's earth or alumina, in fact yield a product, which is free of solid components, but these filtering methods have an adverse influence on the stability of the wax. Thus, waxes purified by filtration through active media quickly become rancid and unusable when stored under normal conditions.

Methods of extraction of the wax components by means of solvents have not been used technically to date. Furthermore, products obtained in such a way still contain residues of solvent and without further purification operations they are consequently unusable for cosmetic or pharmaceutical purposes.

According to the present invention there is provided a method for the separation of valuable substances from plant matter, wherein seed kernels of species of Simmondsia are subjected to extraction in an extraction stage by means of a gas under supercritical conditions, thereby to obtain a phase containing valuable substances, and wherein this phase is transferred into a separation stage, where separation of the valuable substances occurs by providing or establishing subcritical conditions, whereby a substantially pure stable vegetable wax is obtained as the valuable substance, the gas being returned from the separation stage to the extraction stage.

In general, any gas which is physiologically harmless, and which is chemically inert to the plant wax, can be used as the extraction medium; such gases include for example: carbon dioxide, various halogenated hydrocarbons including, CHF3, CF3-CF3,CHCl-CF2,CF CF2=CH2, 2,CF3-CH3, CHF2-CH3,CHF2Cl, CF 3Cl, CF2=CF2, CF2Cl2, CCl3-CHCl2 and C3Fs, sulphur hexafluoride, nitrous oxide, sulphur dioxide, and various hydrocarbons including ethane, ethene, propaner propene, etc. Mixtures of two or more of such gases may be used but carbon dioxide is particularly preferred.

In the extraction stage the seed kernels are exposed to the extraction medium under conditions such that the gas is supercritical both as regards temperature and also as regards pressure. The critical parameters of the gases mentioned above are well-known.

The temperature at which the extraction takes place is preferably in the range of from the critical temperature up to 500C, preferably up to 200C.

above the critical temperature, and the pressure is preferably in the range from the critical pressure up to 500 bar, preferably up to 350 bar above the critical pressure.

In the case where the extraction medium is carbon dioxide, the extraction is conveniently carried out at a temperature in the range of from 31.3 to 800C., preferably 31.3 to 500C., and at a pressure in the range of from 72 to 600 bar, preferably 72 to 300 bar.

From the extraction stage, the phase containing the valuable matter is passed over into the separation stage in which separation of the valuable substances takes place by providing or establishing subcritical conditions. The temperature at which the separation takes place is preferably in the range of from the critical temperature to 1 50C. below the critical temperature, and the pressure is preferably in the range of from the critical pressure to 25 bar below the critical pressure.

In the case where the extraction medium is carbon dioxide, the separation is conveniently carried out at a temperature in the range of 31.3cm. to 1 50C. and at a pressure in the range from 72 to 45 bar.

By providing or establishing subcritical conditions in the separation stage, the solvent power of the extraction medium for the extracted valuable substances is reduced such that the latter separate in the separation stage from the extraction medium and can be carried off during the extraction process, for example through a sluice, or after the extraction process has been completed. Any aqueous components which have also been separated during the extraction process form a separate phase in the separation stage and can be separated from the wax without difficulty.

The extraction medium can be re-used directly without any further purification requiring intensive work and energy, so that no additional emission problems arise. In order to be re-introduced into the extraction stage, the extraction medium merely has to be converted into the supercritical state as regards temperature and pressure, i.e. the alteration in temperature and pressure which was made for separation is cancelled again.

The separated vegetable wax can be removed from the separation stage after the extraction is completed if the present process is conducted as a batch process. However, it is possible to remove the vegetable wax-e.g. via a sluice-if the present process is conducted as a continuous process. With both methods of operation extraction periods of 1 to 12 hours, preferably 3 to 7 hours, are sufficient, to obtain the end product in the purity desired.

With the present method therefore it is possible to obtain the desired product in a short time, thereby minimizing the overheads for apparatus, manpower and energy, and also to avoid any undue burden on the environment. The circulation of the extraction medium offers in particular the possibility of automating the process cycle and, consequently, of conducting the extraction in a particularly economical way.

The vegetable wax obtained can be supplied directly for utilization in foodstuffs, pharmaceutical or cosmetic products etc; however, it can also be hydrated and used as a hydrated product.

The invention will now be illustrated by the following Examples in which specific process conditions are identified as follows:~ Extraction container: Pressure' P Temperature t Separation container: Pressure P2 Temperature t2 Example 1 100 g. of previously ground seed kernels of Simmondsia are loaded into an extraction container and extracted with carbon dioxide gas under supercritical conditions; separation is effected in a separate container and the process conditions are:~ P1 200 bar ti 400C.

P2 50 bar t2 200C.

Extraction time 4h 41 g. of a clear, light yellow wax are obtained and removed from the separation container; in addition, 3.5 g. water are isolated. 55 g. of a pulverulent de-oiled product remain in the extraction container.

The analysis of the wax was as follows C384luid ester approx. 10% C40-fluid ester approx. 30% C42-fluid ester approx. 50% C,-fluid ester approx. 10% Example 2 100 g. of simmondsia seed kernels, stripped of the brown pellicle and ground, are loaded into the extraction container and extracted with carbon dioxide gas under supercritical conditions, and separation is effected under subcritical conditions, the process conditions being P1 300 bar ti 400C.

P2 50 bar t2 200 C.

Extraction time 4h 40 g. of a clear, light yellow fatty acid estermixture are removed from the separation container. In addition 7.5 g. water are separated and 53 g. of a pulverulent residue remains in the extraction vessel.

Example 3 100 g. of ground seed kernels of the Simmondsia chinensis plant are treated with carbon dioxide gas under supercritical conditions and separation is effected under subcritical conditions, the process conditions being P1 150 bar ti 500C.

P2 50 bar t2 200 C.

Extraction time 4h 36 g. of a clear light yellow wax are recovered in.

the separation container, and in addition 3.5 g.

water are separated while 60 g. de-waxed base material remain as a residue in the extraction - container.

Claims

1. A method for the separation of valuable substances from plant matter, wherein seed kernels of species of Simmondsia are subjected to extraction in an extraction stage by means of a gas under supercritical conditions, thereby to obtain a phase containing valuable substances, and wherein this phase is transferred into a separation stage, where separation of the valuable substances occurs by providing or establishing subcritical conditions, whereby a substantially pure stable vegetable wax is obtained as the valuable substance, the gas being returned from the separation stage to the extraction stage.

2. A method as claimed in Claim 1 wherein the gas is carbon dioxide.

3. A method as claimed in Claim 1 or 2, wherein the temperature at which the extraction takes place is from the critical temperature up to 500 C. above the critical temperature.

4. A method as claimed in any one of Claims 1 to 3, wherein the temperature at which the extraction takes place is from the critical temperature up to 200C. above the critical temperature.

5. A method as claimed in any one of Claims 1 to 4, wherein the temperature at which the separation takes place is from the critical temperature to 1 50C. below the critical temperature.

6. A method as claimed in any one of Claims 1 to 5, wherein the pressure at which the extraction takes place is from the critical pressure up to 500 bar above the critical pressure.

7. A method as claimed in any one of Claims 1 to 6, wherein the pressure at which the extraction takes place is from the critical pressure up to 350 bar above the critical pressure.

8. A method as claimed in any one of Claims 1 to 7, wherein the pressure at which the separation takes place is from the critical pressure to 25 bar below the critical pressure.

9. A method for the separation of valuable substances from plant matter, substantially as hereinbefore described in any one of the foregoing Examples.

10. Vegetable wax obtained from seed kernels of species of Simmondsia by the method claimed in any preceding claim.