BG100187A - Method and installation for the non-solvent extraction of natural products by means of microwaves - Google Patents

Abstract

The microwave extraction method involves the steps of placing the biological material in an enclosure without any solvent whatsoever and exposing it to microwave radiation to free at least some of the natural product, and then separating the residual biological material from the extracted natural product. Additionally, it involves the steps of applying reduced pressure in said enclosure during said microwave radiation stage and heating the enclosure during at least most of the microwave radiation stage to compensate the temperature drop resulting from water evaporation from the biological material.

Description

The invention relates to the extraction of natural products contained in biological matter, and in particular, but not only to the extraction of such products from salvage

The extraction of natural products from biological matter can be accomplished by different methods that use or do not use one or more solvents for recovery, depending on the nature of the biological matter used and that of the product or products to be extracted from her. It should be noted that the name given to an extracted product is very often a function of the technology used to obtain it. Thus, nodules, resinoids, oleosmols, which are derived from volatile compounds or from waxy or fatty and non-volatile products, are obtained by the conventional method using at least one organic solvent. Essential oils, generally comprised of volatile aromatic compounds, are generally obtained by steam distillation (hydrodistillation) and / or by mechanical methods.

As an example, the extraction of oleates, essential oils from citrus peels, fish oils, etc. is usually accomplished by physical methods such as grinding and / or pressing without solvents or by hydrodistillation. Except that

the use of such techniques is inexpensive, they also have the advantage that the extracted products (and one biological matter after extraction) do not contain solvent residues and, consequently, they need not be further processed to release them from such residues. products.

However, there are many products that cannot be extracted from natural materials containing them by similar methods and for which it is necessary to use extraction techniques involving organic solvents. With the aid of such techniques, the extracted product is diluted in the solvent and dissolved therein. However, it is then necessary to separate the recovered product from the solvent in order to increase the concentration of the extract. A number of parameters affect the profitability of extraction using solvents, which may include:

- the solubility of the extracted product in the selected solvent;

- diffusion aa the derived product into the solid matrix of the biological matter used.

it is possible to affect the first parameter, especially by varying the operating temperature or concentration of the solvent used.

It is also possible to influence the second parameter, either before or after the extraction stage. In the meantime, the gibouss of the extracted piece could be sensitive to psb, by pre-pgobetting biological matter, which can be expressed by ps-specialty in fragmentation ':, in enzymatic and decomposition, or in drying, and may be biologically affected. matter during the extraction operation itself by warming or dissolving or dissolving or extracting the material through the heating or extraction operation itself. • · · · · · · · · · · · · · · · · · · · · · · · · It is also known from the prior art to apply ultrasound to a mixture of biological mats. second and solvent in order to facilitate the passage of the leachate in the solvent. The mechanical waves made up of ultrasounds allow, indeed, the local generation of one cavitation in biological matter and, therefore, the warming of the latter, which helps to release the extract.

Well-known technique is also to facilitate the extraction of a product from biological matter by subjecting it to microwave irradiation. The impact of microwaves on biological matter is well known today. Indeed, such electromagnetic waves are selectively absorbed by media having a high dielectric constant and, therefore, in the case of biological matter, by water, i. E. mainly from vascular and glandular tissues, and in particular from vacuoles when it comes to matter of vegetable origin »With such absorption, radiant energy is converted into heat, which allows the selective heating of parts of biological matter that absorbs microwaves.

European Patent E1 0398798 discloses a technique for extracting biological microwave products, which comprises the following steps:

- the organic matter is crushed (hot mint, cedar, garlic or LEVlS'ilGUh) having a microwave absorbent ingredient (water);

- place this crushed matter in a transparent or partially transparent solvent relative to the microwaves and absorb less microwaves than the crushed ingredient, for example hexane, ethanol or dichloromethane;

- the mixture consisting of the crushed matter and the solvent is subjected to the action of the microwaves, the crushed matter is heated heated, preferably with the solvent, in order to extract the soluble products;

- residual biological matter is removed from the solvent and

- the extracted product is separated.

Although it provides better profitability of the extraction, the technique described in patent EP 0398798 does not allow to eliminate the aforementioned disadvantages associated with the presence of solvent in the resulting extract.

It should be mentioned that it has already been proposed in the art to extract essential oil from biological matter by irradiation with microwaves and without solvent.

In the article printed in the journal t / stSTst00> volume 4, pp. 43-44, with the headline OSTST

OE 3ZZEGSTSTl OIL discloses a technique for extracting 30D0LD0S essential oil by microwave heating, placing plant samples of 30 to 40 grams, without any solvent, in a beaker inside a microwave oven and subjected to microwave irradiation for 5 hours. minutes. The bottle used is selected to allow the extraction of the essential oil from outside air flow.

Although it allows extraction to take place in a much shorter time than is required for hydrodistillation extraction operations, this method has the significant disadvantage that it requires a high energy cost to achieve extraction, which makes it economically disadvantageous .

All methods of extracting natural products using microwaves and described in the literature can only be realized with a very small volume of biological material compared to the power of the microwaves applied. Usually • · · · ···· - R-ί · · * ··· • · · · · · · · · · · · · · · · · · ₄ · · · · · · · · · · · · · This power varies from 10,000 W to 20,000 W per kilogram of biological material. The maximum power of 2450 MHz microwave transmitters available on the market is 6 kW. Therefore, in order to be used in industry, these methods must be adapted for continuous operation, having a precisely defined small mass at a reasonable power of a microwave source.

It is an object of the present invention to propose a method for extracting natural products using microwaves while avoiding the disadvantages of the prior art methods.

In particular, one object of the invention is to provide such a method that permits solvent-free recovery, i. E. obtaining the extract without any residual solvent.

It is another object of the invention to provide such a method that does not require high energy consumption for a given amount of biological matter processed.

It is another object of the invention to propose an installation for the use of such a method.

The invention relates to a method of microwave extraction of at least one natural product from a biological substance, said method being:

- subjecting microwave irradiation of said biological matter to said chamber to induce evaporation of at least a portion of the water contained in the biological matter and, as a result, to burst the cell structures thereof in such a way as to permit the release of at least one part of the natural product;

- separation of residual biological matter from extraction;

natural product;

the method comprising the following additional steps:

- the simultaneous application of reduced pressure inside said chamber during the operation of microwaves, in order to assist the bursting of cellular structures of biological matter irradiated by microwaves;

- heating said chamber for at least the main stage of microwave application to compensate for the drop in temperature caused by the evaporation of the water from the biological matter;

the combination of said microwave application steps, the use of reduced pressure in said chamber and the heating of the chamber allowing the hydrodistillation of the natural product by entraining it in water vapor exiting said biological matter.

Such a method can be suitably applied to all natural biological materials, whether of animal, plant or microbial origin, provided they contain at least about 30% water. This method can be used, in particular, for the extraction of essential oils from plants, animal tissues, and in particular from fish, but also from algae, microalgae and even, possibly, microorganisms. Of course, this biological matter may, depending on its nature, be crushed before being placed in the chamber to maximize the effects of microwaves.

The process according to the invention allows the hydrodistillation of the product to be extracted, not by introducing the zod from outside during the process, but by the water contained in the treated biological material.

It should be noted that within this description, this water will be called constitutional water, even when it is pre-introduced into biological matter if the latter is provided in dehydrated form and needs to be re-moistened.

The method according to the invention therefore consists in subjecting the treated biological matter to microwave irradiation, in the absence of a leaching solution allowing the contents of the cells of that matter to be discharged outwards. To facilitate this phenomenon and in order to azeotropically capture the extracted product, the pressure in the chamber was reduced. This decrease in pressure allows, on the one hand, to increase the mechanical effect on the walls of the cells of biological matter and, on the other, to increase the volatility of the azeotropic mixture composed of the product being extracted and the water vapor. According to the invention, simultaneous heating of the chamber allows to compensate for the rapid decrease in temperature caused by the evaporation of the constitutional water under the influence of the pressure drop in the chamber. Such a drop in temperature is truly capable of completely neutralizing the effects of microwaves.

The method according to the invention provides many advantages.

In addition to obtaining solvent-free extracts, this method allows, compared to conventional hydrodistillation, to obtain an extract of equivalent composition and profitability in a significantly shorter time. While conventional hydrodistillation typically takes hours, the reduced-pressure hydrodistillation time of the invention lasts minutes. For some products, using this method is possible. • · · · · · · · · · · ·

But the production of a certain amount of extract is ten times faster than in the case of classical steam distillation.

Moreover, the method according to the invention consumes much less energy than the microwave extraction methods known in the art. For the same amount of biological matter processed, the energy consumed by the process of the invention is also less than that required by hydrodistillation.

In hydrodistillation, it is necessary to heat the biological matter and the added water, the mass of which can represent up to 10 times the mass of biological matter

Finally, it should be noted that the residual biological matter obtained at the end of the method is in the dry state, since the constitutional water it contained served to entrap the extracted product and the method does not require the addition of water from outside. Therefore, this residual material will be easily decomposable and possibly recycled as fuel.

Preferably, said step of the method according to the invention, consisting in the simultaneous application of reduced pressure, involves subjecting the chamber to depression cycles.

According to one variant of that step of separating the residual interior of the invention, said biological matter from the extract consists in:

- cooling the water vapor containing said extracted product;

casting of the liquid mixture obtained by cooling and

- the separation of the extracted natural product and the water resulting from this casting.

Although another advantage of the method is that much less residual water is obtained than in conventional hydrodistillation methods, at least a portion of said water obtained during this casting is injected into the chamber to hydrodistill the natural product, remaining in the residue of biological matter.

Moreover, the heating step is preferably carried out at a temperature lower than 100 ° C. It should be noted that it is better to keep the temperature below 75 to allow the extraction of products which tend to decompose under heat.

The microwaves used in the microwave irradiation step are preferably at least 300 MHz in frequency. However, it should be noted that in many countries the use of frequencies is strictly regulated and that, for example in France, only 915 MHz and 2450 MHz are permitted for microwave-generating industrial equipment.

In addition, said microwave irradiation step is best performed at a power of about 100 T7 to about 10,000 W per kilogram of processed product.

In one of the embodiments of the method, said microwave irradiation step is carried out with mechanical agitation of said biological matter. This agitation allows the microwave effects on biological matter to be increased.

The invention also relates to an installation for the application of a similar method, characterized in that it comprises:

- a chamber equipped with microwave generators within said chamber and having a double thermostatic wall;

- heating means for adjusting the tem- »L r-f · .......

- · χι> · - · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · the outline of said double thermostatic wall;

means for reducing the pressure inside said chamber;

the means of separation are extracted at its outlet from said camera.

Preferably, said extraction means comprise a means of cooling the steam containing the extraction.

It is also preferred that said installation have means for cycling said means to reduce the pressure inside the chamber.

It is recommended that said camera be provided with agitators.

Finally, it is recommended that said installation be provided with means to redirect the residual water obtained by the means of separation to the interior of said chamber.

The invention, as well as the advantages it provides, will be better understood by the journal of the example examples given below with the relevant drawings, where:

- Figure 1 is a schematic view of an installation according to the invention;

- Figure 2 shows the variation of the chamber pressure and temperature of the biological matter, within the first embodiment of the method according to the invention, with the schematic installation of Figure 1 for extracting peppermint oil;

- Figure 3 shows the variation in the yield of hot mint essential oil obtained from the first example of application of the method;

«·« · · · · · · · · · · · · · · ·

- Figure 4 shows the change in chamber pressure and temperature of biological matter, in a comparative example of extracting hot peppermint oil;

- Figure 5 shows the variation in the yield of peppermint essential oil in the comparative example;

- Figure 6 shows the change in chamber pressure and temperature of biological matter, in the context of a second embodiment of the method according to the invention, for extracting essential oil from sage;

- Figure 7 shows the variation in yield of sage tea essential oil obtained from the second embodiment of the process according to the invention.

Figure 1 schematically shows an installation for the extraction of natural products from biological matter. Such an installation is provided with a single chamber 1 provided with means 2 allowing microwaves to be generated within the space confined by the chamber. In accordance with statutory provisions, these means 2 allow microwaves to be transmitted at a frequency of 2450 MHz. (It should also be noted that it is possible to use a 915 MHz microwave generator, this frequency is also permitted in France).

The chamber 1 is provided at its bottom with agitators 9 representing a single turbine with three blades that allow the biological matter to be agitated while it is inside the chamber 1 when it is exposed to microwaves. Such stirring makes it possible to increase the exposure of biological matter to microwaves and to avoid the possibility that some areas may not be sufficiently irradiated to successfully complete the extraction operation.

In accordance with the present invention, chamber 1 is

4 4 4 4 4 4 «4« • · I rt · ······ • - · · 3Z · “* * ····· f

4 4 4 4 4 · 4 · 4 * ··· 44 444 connected on the one hand with the means 5, allowing to reduce the pressure inside it and, on the other, with the means for the separation of the extracted natural product from biological matter under the influence of microwaves. The means 5 for reducing the pressure in the chamber may be any means used to create a partial vacuum inside a chamber, such as, for example, a simple water pump or a jet pump. In the context of the present example, the means for separating the extracted product comprise a channel 11 located at the top of the chamber 1 around which cooling means 7 formed by a coil flowing coolant are provided.

Channel 11 allows the recovery of the vapors obtained by the action of microwaves on the biological matter and in which the vapor is located in the essential oil. Thanks to the cooling means 7, this water vapor condenses. An outlet 12 is provided at the outlet of channel 11 for the separation of these condensed vapors and for the extraction of the essential oil. The residual residual water after separation is diverted from another channel 10 to the chamber 1 where it is recycled to supplement the recovery.

In order to allow heating inside the chamber 1 to compensate for the decrease in temperature due to the pressure reduction caused by the vacuum pump 5, the chamber 1 has a double thermostatic wall 3 connected to the heating means 4.

The installation described above was used for the application of the microwave extraction method of the present invention for extracting hot peppermint oils (Examples 1 and sage (Example 3)).

• · • ·,%. · · · · · · · · · · · · · · · · * · · • · · · · · · · · · · · · ·

EXAMPLE 1

One kilogram of peppermint / Peppermint Mint, Hungarian variety / containing 15% dry matter, was placed inside chamber 1. The heating means 4 were adjusted so that the thermostatic wall 3 would create a temperature of about 70 ° C inside the chamber 1. and the stirring means 9 were activated to have a speed of 40 rpm.

The power of the microwave generating means 2 is 1150 W and the reflected power varies between 170 W and 220 W. During the extraction operation, which lasted 15 minutes, the effectively absorbed power was therefore 930 to 980 VV.

During extraction, pump 5 was started so that the pressure was reduced to 250 mb. This pressure drop occurred after the 5th, 10th and after the 13th minute.

In addition, the temperature of the cooling medium circulating in the coil 7 was fixed at 5 ° C to cause condensation of the vapors obtained under the influence of microwaves on hot mint and containing the essential oil.

The change in the temperature of the mint in the chamber and the pressure therein is presented in Figure 2. Under the influence of microwaves, the temperature of the material quickly equalizes with the ambient temperature to about 75 ° C. As soon as a partial vacuum / 250 mb / due to the pump 5 is created inside the chamber, the temperature drops. This drop in temperature is quickly compensated by heating the camera so as not to reduce the effect of the microwaves.

In Figure 3, after extraction lasting 15 minutes and after 3 cycles of depression, 1.52 ml of essential oil (or 1.01 ml yield per 100 g of dry matter) were recovered.

· · · · · · · · · · · ·

Hydrodistillation of the peppermint residue obtained from such a microwave extraction operation allowed the extraction of less than 50 mg of essential oil. The method according to the invention therefore enables the production of essential oil to be near the exhaustion of biological matter.

Comparison of the chromatographic profiles in the gas phase of two essential oils obtained by the extraction method according to the invention and by classical hydrodistillation did not show much difference in their composition.

EXAMPLE 2

The same amount of hot mint as in Example 1 was processed using the same operating methods as in Example 1, but with pump 5 running continuously so that the pressure inside chamber 1 was fixed at 250 mb for the entire duration of the extraction operation.

The change in the mint temperature and the chamber pressure are given in Figure 4.

Referring to Figure 5, the yield of essential oil in this example was only 0.2 ml per 100 g, i. five times smaller than in Example 1. 1150 mg of essential oil were recovered in the remaining mint after the extraction operation. These results show the importance of periodically, according to the invention, a reduction in the pressure inside the chamber.

EXAMPLE 3

500 grams of sage tea / salvia officeis L / representing 25% dry matter were placed inside chamber 1. The heating means 4 were adjusted so that the thermostatic wall 3 would enter inside the chamber 1 a temperature of about 70 ° C and the agitators 9 were activated so that they had a speed of 40 rpm.

The power output from the means 2 for generating my roof is 1000 W, and the reflected power varies between 150 W and

200 W. During the extraction operation, which lasted for 10 minutes, the effective power absorbed was therefore from 800 to 850 VV.

During extraction, pump 5 was activated to reduce the pressure to 250 mb. This pressure reduction was performed after 3.5 minutes and after 7 minutes.

In addition, the temperature of the cooling medium circulating in the coil 7 was fixed at 5 ° C to cause condensation of the vapors obtained by the action of the microwaves on the peppermint and containing the essential oil.

The variation of the temperature of the sage you are in, and the pressure inside, is shown in Figure 6.

Considering Figure 7, after 10 minutes of extraction and 2 cycles of depression, 3.06 ml of essential oil / m.p. yield of 2.55 ml per 100 g dry matter / ₀

The theoretical yield for classical hydrodistillation of the same amount of sage is 2.77 ml per 100 g, indicating that the use of the process according to the invention allows the extraction of more than 90% of the essential oil from the sage treated.

The examples of use of the invention described herein do not limit its use. In particular, a shorter or longer duration of microwave operation may be envisaged, different microwave frequencies may be used, or steam extracted by a technique other than that described without departing from the scope of the invention. the rope

Claims (13)

1.— A microwave extraction method for at least one natural product of biological matter, said method comprising the steps of: - placing said biological matter in one chamber, in the absence of any solvent; - subjecting microwave irradiation to said biological matter present in said chamber in order to provoke the evaporation of at least a portion of the water contained in said biological matter and, as a consequence, the bursting of the cellular structures of said biological matter, to allow the release of at least one part of said natural product; - separation of residual biological matter from the extracted natural product; characterized in that it comprises the following additional steps consisting of: - simultaneous application of reduced pressure inside the chamber during microwave operation, in order to assist the bursting of the cellular structures of said biological matter irradiated by microwaves; - heating the chamber for at least the main microwave application stage to compensate for the drop in temperature caused by the evaporation of biological matter water; microwave- * · · «· · • · · · - The combination of said steps of application of the filaments, the use of reduced pressure in the chamber and the heating of the chamber permitting the hydrodistillation of the natural product by entraining it in the water vapor exiting said biological matter. Method according to claim 1, characterized in that said step for applying a reduced pressure consists in subjecting the inside of said chamber to depression cycles. Method according to one of Claims 1 or 2, characterized in that said step of separating the residual biological matter from the extract consists of: - cooling the water vapor containing the extracted natural product; - the casting of the liquid mixture obtained by such cooling; and - the separation of the extracted natural product and the water resulting from that casting. Method according to claim 3, characterized in that at least a portion of said water obtained during the casting step is injected into the chamber to effect the hydrodistillation of the natural product remaining in the remainder of the biological matter. Method according to one of Claims 1 to 4, characterized in that the heating step is carried out at a temperature lower than 100 ° C. Method according to one of Claims 1 to 5, characterized in that the microwaves used at the microwave irradiation stage have a frequency of at least 300 MHz. Method according to one of claims 1 to 6, characterized in that the microwave irradiation step is carried out at a power of about 100 W to about 10,000 watts per kilogram of processed product. Method according to one of Claims 1 to 7, characterized in that said microwave irradiation step is carried out with mechanical agitation of the biological matter. Installation for the application of the method according to one of claims 1 to 8, characterized in that it comprises: - one chamber / 1 / provided with microwave generation means / 2 / inside said chamber / 1 / and having a double thermostatic wall / 3 /; - heating means (4) for controlling the temperature of said double thermostatic wall (3); means for reducing the pressure (5) inside said chamber; means for separating the extract (6) at its outlet from said chamber. 10. Installation according to claim 9, characterized in that said extraction means (6) comprise cooling means (7). Installation according to claim 9 or 10, characterized in that it has means (8) which actuate the means (5) allowing a cyclic pressure reduction inside the chamber. Installation according to one of Claims 11 to 11, characterized in that said chamber (1) is provided with stirring means (9). • · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · Installation according to one of Claims 9 to 12, characterized in that it has means (10) for redirecting the residual water obtained by the means for separating the extraction to the interior of said chamber (1).