ITMI20082302A1 - REACTOR FOR IMMISCIBLE LIQUID REAGENTS. - Google Patents

Description

Description of the patent application for industrial invention entitled: "Reactor for immiscible liquid reagents"

The invention relates to a reactor for immiscible liquid phase reagents, in particular a reactor for the production of biodiesel. The invention also relates to a plant comprising this reactor and a method for using this reactor.

In the chemical industry there are numerous reactions that take place between two liquid phases that are immiscible to each other. A reaction of this type that has become very important in recent times is, for example, the reaction of oils and / or fats with alcohols to obtain the so-called biodiesel. The oil phase and the alcohol phase, which are partially immiscible, give rise to a biphasic system.

Biodiesel, which chemically corresponds to a mixture of long-chain fatty acid esters, is obtained through a process of transesterification of vegetable oils and / or animal fats with light alcohols, preferably with methanol, in the presence of alkaline catalysts. Current production technology is based on the use of basic homogeneous catalysts such as sodium hydroxide (NaOH), potassium hydroxide (KOH), or sodium methylate (CH3ONa).

The transesterification reaction occurs through a staged process in which triglycerides are converted to diglycerides, which are then converted to monoglycerides, and finally to glycerol. At the end of the reaction, therefore, a phase consisting of a mixture of esters and a phase containing glycerol as a co-product are obtained.

The configuration of the plants and the reaction conditions are generally similar to those described in US patent 4,303,590. This configuration provides for a first reaction stage carried out at the boiling temperature of methanol (64.7 ° C), for a reaction time between 30 and 120 minutes, with a concentration of the catalyst between 0.1% and 1% by weight with respect to the oil. At the end of the first stage, the glycerol produced from the ester phase is separated. The latter is subjected to a second stage of transesterification for a time between 5 and 60 minutes.

The reaction rate in transesterification catalyzed by homogeneous bases is very high, so much so that in stirred reactors this is often dominated by the transfer of matter due to the presence of two immiscible phases. In this regard, see the publication of D.G.B. Boocock, S.K. Konar, V. Mao, C. Lee, and S. Buligan in the Journal of the American Oil Chemists' Society, Volume 75, 1998, pages 1167 to 1172 (JAOCS 75 (1998) 1167-1172 for short).

Although the linearity of the increase in the reaction rate with the concentration of the catalyst has been demonstrated, at a certain concentration value this is no longer true for the problems related to the transfer of matter. For example some authors such as Narváez, S.M. Rincón, and F.J. Sánchez, (JAOCS 84 (2007) 971-977) working in stirred reactors at 400 rpm they studied the effect of the catalyst concentration in the transesterification reaction of palm oil with methanol, at a temperature of 50 ° C and oil ratio / methanol equal to 1: 6. These studies have shown that the effect of the catalyst concentration is important in the range between 0.2% and 0.6%, while it is no longer significant in the range between 0.6% and 1%, due to the limitations due to the transfer of matter. between phases.

Darkono and Cheryan (JAOCS 77 (2000) 1263) report that at 60 ° C, using 0.5% by weight of KOH as catalyst, in a stirred reactor, the initial phase of the reaction is controlled by the transfer of matter.

Due to the problems associated with the two-phase system, fully mixed batch reactors (called batch type reactors) or Continuous Stirred-Tank Reactor or CSTR are used industrially. In any case, the problems related to the transfer of matter increase considerably with the increase in the size of the reactors, so the reaction times in industrial batch reactors, and the contact times in CSTR reactors are generally greater than 30 minutes.

In order to use flow reactors without agitation, the use of continuous piston flow reactors (called plug-flow reactors) is proposed in the document US 2003/0032826 arranged in series and interspersed with static mixers in which the flow of the oil phase is turbulent (Reynolds number> 2100). More recently, to overcome the problems related to phase transfer, the use of microreactors is proposed in WO 2007/142983. In these reactors the dimensions of the channels are between 50 µm and 300 µm. These reactors show exceptional performance in liquid-liquid reactions due to the high transfer rate of matter and heat.

When two fluids are injected into the microreactor, their mixing takes place in a laminar regime without turbulence (low Reynolds number). In fact, due to the very small diameters of the channels (d <300 µm) the time τ required for the reagent molecules to diffuse through the interface becomes extremely small since it depends on the following relationship: τ = d <2> / D

(where D = Diffusion Coefficient)

In one of the examples reported in WO 2007/142983, using a microreactor with channels having a diameter of 100µm, with a concentration of NaOH catalyst equal to 1% by weight with respect to the oil, and with an oil / methanol ratio equal to 1: 7.2, after 10 minutes of contact time a conversion to methyl esters equal to 91% was obtained. However, as the diameter of the microreactor channels increases, performance deteriorates. In fact, for the same residence time, with a microchannel diameter equal to 200µm, a conversion of 85% is obtained.

In addition, the use of microreactors of the type proposed by WO 2007/142983 on an industrial scale, therefore for high tonnage productions, is problematic due to the difficulty of using a large number of such microreactors and the high cost that results.

The intensification of the biodiesel production process is on the other hand a current objective in the industry and the need is therefore felt to develop a reactor characterized by high yields for short residence times that is also simple and economically advantageous to implement. .

The object of the present invention is to at least partially solve the drawbacks highlighted in relation to reactors, plants and methods of the known type.

In particular, the object of the present invention is to make available a reactor for carrying out reactions between immiscible liquids, such as that for the production of biodiesel, with a high yield and productivity.

The object and the tasks indicated above are achieved by a reactor according to claim 1, by a plant according to claim 7 and by a method according to claim 11.

The characteristics and further advantages of the invention will result from the description, given below, of some examples of embodiment, given by way of non-limiting example with reference to the attached drawings, in which: Figure 1 represents a schematic view of a plant comprising a reactor according to the invention;

Figure 2 schematically represents a side view of a reactor, with a single cavity, according to the invention;

Figure 3 schematically represents the section along the line III-III of Figure 2;

Figure 4 schematically represents a plan view of the reactor of Figure 2;

Figure 5 schematically represents the section along the trace V-V of Figure 4;

Figure 6 represents a front view of a reactor, with multiple cavity, according to the invention;

Figure 7 represents a side view of the reactor of Figure 6;

Figure 8 represents a perspective view of an element of a possible reactor according to the invention;

Figure 9 schematically represents the operation of a possible reactor, with multiple cavity, according to the invention.

The present invention refers to a reactor 20 for at least two reactants supplied in two liquid phases 12 and 13. The reactor comprises an inlet 21 suitable for receiving the two liquid phases 12 and 13; an outlet 22 suitable for emitting the products 14 of the reaction; and a channel 23 suitable for receiving a continuous flow of reagents and / or products. The channel 23 includes, at least in one section, a gap 28 enclosed between two plates 24 arranged at a distance of at least 0.5 mm. The channel 23 comprises means 25 for promoting turbulence in the continuous flow of reactants and / or products. The reactor 20 further comprises means 26 for generating a heat exchange between the walls and the continuous flow of reactants and / or products.

These reactors according to the invention are hereinafter referred to as plate reactors.

In accordance with some embodiments, the plates 24 of the reactor 20 according to the invention are arranged at a distance not exceeding 10mm, preferably at a distance between 1mm and 3mm, even more preferably at a distance between 1.5mm and 2mm .

In accordance with some embodiments (for example that of figures 2 to 5) the plate reactor 20 comprises a single interspace 28 enclosed between two plates 24. In accordance with other embodiments (for example those of figures 6 a 9) the plate reactor 20 comprises a plurality of cavities 28, each enclosed between two plates 24. These solutions are described in detail below.

In accordance with some embodiments of the invention, the means 25 for promoting turbulence in the continuous flow of the reactants and / or the product comprise corrugations or knurls of the surface of the plates 24. See for example Figures 8 and 9. In such embodiments the distance between the plates 24 can be defined by the resting of the ridges of the corrugations of one plate on the valleys of the corrugations of the adjacent plate.

In accordance with some embodiments of the invention, the means 25 for promoting turbulence in the continuous flow of the reactants and / or the product comprise filling material comprised between the plates 24. This filling material can take the form of granules, spheres. , flakes, filaments, membranes or the like. In accordance with some of these embodiments, the filling material comprised between the plates 24 is inert. It therefore does not participate in the chemical reaction between the reactants but has the sole function of promoting turbulence in the flow. In other embodiments, the filling material comprised between the plates 24 is instead suitable for carrying out catalytic activity.

In accordance with an embodiment of the invention, the means 26 for generating a heat exchange between the plates 24 and the continuous flow of the reactants and / or the product comprise means 4 for heating the plates to a temperature between 10 ° C and 300 ° C, preferably between 50 ° C and 200 ° C.

In accordance with the embodiment of Figures 2 to 5, the means for generating the heat exchange are plates 26 placed against the plates 24 of the reactor. The plates 26 may for example comprise electric resistors (suitable for heating) and / or a fluid circuit (suitable for heating or cooling). The temperature control of the plates 26 can be carried out by means of a circuit, known per se, not shown in the figures for the sake of simplicity. In this way it is possible to keep the plates 24 of the reactor 20 at a predetermined temperature.

In accordance with the multiple cavity embodiments, the plate reactor 20 can take a shape similar to that of a plate heat exchanger (see Figures 6 to 9). The plate reactors 20 according to the invention comprise a plurality of plates arranged as in the diagrams of figures 7 (in which the reactor is closed) and 9 (in which the reactor is open to show the flows that are generated inside it). The plate reactor can be sealed or can be opened to allow inspection, cleaning, and / or maintenance. In the case of sealed reactors, the hydraulic and mechanical seal between the plates is guaranteed by brazing. In the case of openable reactors, on the other hand, the hydraulic seal is ensured by elastomeric seals 27 (see Figures 8 and 9) while the mechanical seal is ensured by external clamping means (not shown for simplicity). The particular elastomeric seals 27 allow the formation of two channels crossed by the two fluids involved, which can be fed in co-current or in counter-current. Each of the two channels comprises a series of air spaces 28 comprised between the plates 24 in the manner described above. These gaps can be arranged in parallel and / or in series.

In the case of plate reactors, the means 26 for generating the heat exchange between the plates 24 and the reactants and / or the product comprise a circuit in which a temperature-controlled service fluid circulates. The service fluid used in this type of systems can be, in a per se known manner, diathermic oil, water, ethylene glycol or the like. In the embodiment of Figure 1, the means 26 for generating the heat exchange further comprise a boiler 4 suitable for heating and circulating the service fluid at a predetermined temperature. In other embodiments, the means 26 for generating the heat exchange comprise a refrigeration unit suitable for cooling and circulating the service fluid at a predetermined temperature.

The advantages of using a plate heat exchanger compared to the traditional type of shell and tube heat exchangers can be summarized <in some fundamental points:>

• All the volume occupied by the fluids in the plate exchanger <participates in the heat exchange without by-pass and dead zones.>

• The passages inside are linear and therefore the pressure drops are used only to increase turbulence and improve the <heat exchange.>

• The exchange coefficient is two to three times higher than that of a shell and tube exchanger; therefore, with the same potential, the dimensions of the plate heat exchanger are much smaller, allowing it to be placed in confined spaces.

Plate exchangers are used above all in those cases where low exchange coefficients due to the characteristics of the liquid, or at low speeds, require special measures to increase the coefficient itself. For openable exchangers, the limits of use, imposed by the elastomer seals, are normally temperatures not exceeding 200 ° C and pressures not exceeding 1.0Mpa. In the case of brazed heat exchangers, the temperature can reach over 300 ° C while the pressure can reach 2.5MPa since the only limit, usually less stringent, is that imposed by the external clamping means.

The plates 24, and the relative external clamping means, are available with different unit surface sizes and with herringbone corrugations of different angles. The number of plates 24 for each exchanger varies according to the flow rates and temperatures of the two fluids. The distance between the plates is obtained by embossing obtained from the mold, which keep it constant even in the presence of strong differential pressures. The corrugation pattern of the plates induces a highly turbulent type of flow for relatively low flow rates. The high turbulence in plate heat exchangers therefore greatly increases the transfer rate of matter and heat at low flow rates.

The shape of the corrugation first induces a separation and then a rejoining of the flow, each time determining the regeneration of the boundary layer, which influences the heat transfer coefficient.

The flow within the cavities 28 between the plates 24 is subject to a series of periodic changes of directions encountering peaks and troughs. The flow pattern is complex, also due to the presence of secondary swirling motions, also known as Goetler, along the section and it is believed that the type of local flow controls the transfer. It has been found that the particular geometric characteristics of a plate exchanger, combined with the inlet flow rates of adequate reagents, are found to be particularly effective in the transesterification reaction of oils and / or fats for the production of biodiesel. Specifically, a mixture of the two liquid phases 12 and 13 containing the two reactants is circulated in a first channel 23 of the plate exchanger. A service fluid, as described above, can be advantageously circulated in the second channel to control the temperature of the reaction.

Surprisingly, it has been found that by increasing the inlet flow rates of the two liquid phases 12 and 13, conversions far superior to those expected are obtained, taking into account the reaction kinetics reported in the literature. For such kinetics, see for example what published by H. Noureddini and D. Zhu, (JAOCS 74 (1997) 1457) or by G. Vicente, M. Martinez, J. Aracil and A. Esteban (Industrial & Engineering Chemistry Research 44 , (2005) 5447-5454).

Furthermore, it is observed that, by increasing the feed rate of the two liquid phases 12 and 13, both the conversion and the yield unexpectedly increase.

The present invention also relates to a plant 1 comprising a plate reactor 20 as described above. The plant 1 according to the invention also comprises means 2 and 3 for the continuous feeding of the two liquid phases 12 and 13 to the reactor 20 and means 6 for the continuous outflow of the products 14 from the reactor 20. The means 6 for the outflow of the products 14 can advantageously flow into a collection tank 7 of the closed type.

In accordance with an embodiment of the invention, the plant 1 also comprises means 11 to maintain the pressure inside the plant between 0.01 and 2.5 MPa, preferably between 0.1 and 1 Mpa. In accordance with some embodiments of the invention, for example the one schematized in Figure 1, the means for regulating the pressure inside the system comprise a source 11 of nitrogen (N2) under pressure. This nitrogen source 11 is suitable for filling the part of the collection tank 7 of the closed type which is not occupied by the product 14. It is thus possible, inside the collection tank 7 and of the system 1, to maintain a pressure different from that atmospheric pressure.

In accordance with an embodiment of the invention, the plant 1 further comprises means 50 for coarsely pre-mixing the two liquid phases 12 and 13 upstream of the reactor 20. In accordance with some embodiments, the means 50 for pre-mixing - coarsely mixing the two liquid phases 12 and 13 comprise a static mixer of a per se known type. Advantageously, the means 50 for coarsely pre-mixing the two liquid phases 12 and 13 can also comprise means for preheating the mixture upstream of the reactor 20.

The plant 1 can advantageously comprise a derivation suitable for taking samples 15 of the products 14 to check their characteristics. In this case, a three-way valve 9 allows a part of the flow of the products 14 to be diverted and the samples 15 to be taken at specific times. The derivation from the main line 6 of the system includes an effective condenser 10.

The invention also relates to a method for obtaining products 14 from a chemical reaction between at least two reagents provided in two liquid phases 12 and 13. The method includes the steps of:

- Feeding the two liquid phases 12 and 13 to a reactor 20 having a reaction chamber shaped like a channel 23 suitable for receiving a continuous flow of the two liquid phases 12, 13 and / or of the products 14, in which the channel 23 comprises, at least in one section, a gap 28 enclosed between two plates 24 arranged at a distance of at least 0.5 mm, and in which the channel 23 comprises means 25 for promoting turbulence in the continuous flow of the two liquid phases 12, 13 and / or of the products 14;

- generating a heat exchange between the plates 24 and the continuous flow of the two liquid phases 12, 13 and / or of the products 14; And

- Collect the products 14 at the exit 22 of the reactor 20.

According to an embodiment of the method, a liquid phase 12 comprises an oil and / or a fat of vegetable or animal origin; the other liquid phase 13 comprises a light alcohol; the two liquid phases are therefore immiscible with each other; the reaction is a transesterification; and the products 14 of the reaction include biodiesel and glycerin.

According to an embodiment of the method, the oil of vegetable origin is selected in the group comprising: rapeseed oil, palm oil and sunflower oil, castor oil, soybean oil, cottonseed oil, peanut oil, algae oil, jatropa oil (jatropha curcas). Light alcohol is ethyl alcohol or preferably methyl alcohol.

According to an embodiment, the method further comprising the step of mixing to the two reactants also a basic homogeneous catalyst selected from the group comprising: sodium hydroxide (NaOH), potassium hydroxide (KOH) and corresponding alkoxides with preference for methoxide sodium (CH3ONa) or sodium ethoxide (C2H5ONa).

The advantages of this invention reside in the possibility of obtaining high biodiesel productivity.

In the following examples, for illustrative and not limitative purposes of the present invention only, biodiesel production tests are described in detail, varying the operating conditions.

Example 1

Effect of residence time

In this example and in the following examples, a brazed plate reactor 20 was used with a process volume of 202 ml and a volume for the service fluid of 250 ml, consisting of twenty plates 24 arranged at an average distance between 1.5mm and 2mm from each other, as described in figures 6 to 9.

This example shows the results achieved, in terms of conversion to methyl esters, for the transesterification reaction in the reactor 20 described above.

The transesterification reaction was carried out at a temperature of 60 ° C, using an oil-methanol molar ratio equal to 1: 6, and as catalyst potassium hydroxide (KOH), with a concentration by weight with respect to the oil equal to 1 % by weight.

The reaction conditions are reported in table 1.

Table 1: Reaction conditions used for the transesterification reaction of Example 1.

Temperature Pressure Catalyst Catalyst / oil Methanol / oil (° C) (MPa) (g / g) (mol / mol) 60 0.1 KOH 0.01 6

For the reaction, plant 1 schematised in Figure 1 was used. The oil phase 12 and the methanol phase 13 are flushed by means of two piston pumps 2 and 3, first in a premixer 50, maintained at the reaction temperature, and then at the reactor 20. A three-way valve 9 allows samples 15 to be taken at specified times. These samples 15 are previously cooled with a condenser 10, filled with Raschig rings. The three-way valve 9 also allows the products 14 to be sent to a collection tank 7 maintained at the operating pressure by means of a flow of nitrogen.

The collection tank 7 is advantageously used for the reactions carried out under pressure. For reactions at atmospheric pressure it is possible to operate without it.

The oil phase 12 and the methanol phase 13, in which the catalyst was previously dissolved, are flowed to the reactor 20 and heated to the reaction temperature of 60 ° C. Once the stationary conditions are reached, the reaction takes place, according to the established time.

If operating under pressure, the zero time is considered to be the time corresponding to the attainment of the desired temperature and pressure.

Samples 15 taken during and at the end of the reaction contain the ester phase, the glycerine phase, the catalyst, the oil and the unreacted methanol.

In order to remove the glycerin and the catalyst from the ester phase, each sample was subjected to a preliminary treatment.

To remove the glycerin and the catalyst, the reaction products 14 were washed with small quantities of a 20% sodium chloride solution. Two phases were formed which were not clearly distinct: a lower, transparent one, containing glycerin and an upper, yellowish one, containing the mixture of methyl esters. After having centrifuged the biphasic mixture, the upper phase, in which the methyl esters are contained, was removed and anhydrified with a small quantity of anhydrous magnesium sulphate; the ester phase was then analyzed by nuclear magnetic resonance (H-NMR).

The transesterification reactions of soybean oil with methanol, described in this example, were carried out with different residence times, in this case equal to respectively 300, 120, 60 and 30 seconds. These contact times are achieved by working with total inlet flow rates of 40, 100, 200, 400 ml / min. The table shows the oil and methanol flow rates used for each test.

Table 2: Flow rates and residence time for each transesterification test of Example 1.

Flow Rate Total Flow Time Oil Flow

Test Methanol residence (s) (ml / min) (ml / min)

(ml / min)

1 300 40 31.8 8.2

2 120 100 79.5 20.5

3 60 200 159 41

4 30 400 318 82

The results obtained in terms of conversions to methyl esters are summarized in Table 3.

Table 3: Conversions into methyl esters obtained for the transesterification reactions, carried out with different residence times.

Residence time Conversion into methyl esters Test

(s) (%)

1 300 54.5

2 120 61.5

3 60 78

4 30 83

From the reported values it can be deduced that by increasing the flow rate of the two liquid phases 12 and 13, and therefore by decreasing the contact times, the conversions to methyl esters increase. This is probably due to the accentuation of the phenomenon of turbulence in channel 23 of reactor 20 with the increase in flow rates. The remixing between phases 12 and 13 gradually cancels the limitations to the transfer of matter allowing to approach the chemical regime. In other words, the chemical regime would be characterized by very high reaction rates never previously shown in other types of reactor.

Example 2

Effect of temperature

In this example, the effect of the temperature for the transesterification reaction of soybean oil with methanol conducted in the reactor 20 described above is studied.

The reaction was carried out under the same conditions described in example 1, using potassium hydroxide (KOH) as a catalyst in a concentration equal to 1% by weight with respect to the oil, and methanol / oil in a molar ratio of 6: 1.

For the transesterification tests to which this example refers, the inlet flow rate of the liquid phases 12 and 13 was kept constant for

a value equal to 400 ml / min, in order to achieve a residence time of 30 seconds.

The temperature, on the other hand, was made to vary and the values of 60 ° C, 90 ° C and 103 ° C were used.

The plant schematized in Figure 1 was used and for the tests conducted at 90 ° C and 103 ° C, the pressure was higher than atmospheric, to keep the methanol in the liquid phase.

Tables 4 and 5 summarize the operating conditions adopted for the tests described in this example.

Table 4: Reaction conditions used for the transesterification reaction of Example 2.

Flow Time

Catalyst Catalyst / oil Methanol / oil Total residence

(Pellets) (g / g) (mol / mol) (s) (ml / min)

30 400 KOH 0.01 6 Table 5: Temperatures and pressures adopted for the transesterification tests of example 2.

Temperature Pressure

Trial

(° C) (MPa)

5 60 0.1

6 90 0.3

7 103 0.4

Once the conditions of stationarity of temperature and pressure were reached, 15 samples were taken, which were promptly cooled, treated to remove the catalyst and glycerin, and analyzed with H-NMR. The conversion values obtained in methyl esters are shown in table 6.

Table 6: Conversions into methyl esters obtained for the transesterification reactions, carried out at different temperatures.

Temperature Conversion into methyl esters

Trial

(° C) (%)

5 60 83

6 90 85

7 103 88

From the reported results it can be concluded that increasing the temperature and pressure improves the yields of methyl esters.

Example 3

Effect of the catalyst

This example shows the transesterification reaction carried out in the reactor using sodium methylate (CH3ONa) as catalyst, instead of potassium hydroxide (KOH).

We proceeded in a similar way to examples 1 and 2, and the operating conditions are summarized in table 7.

Table 7: Conditions used for the transesterification reactions of Example 3.

Catalyst Time / Methanol Flow Rate /

Oil residence temp. Total oil

(° C) (s) (g / g) (ml / min) (mol / mol)

30 0.01 400 6 90 The results obtained are shown in table 8.

Table 8: Conversions into methyl esters obtained for the transesterification reactions, with different catalysts.

Conversion into methyl esters Test Catalyst

(%)

8 CH3ONa 96

6 KOH 88

From the data reported it can be deduced that, by using sodium methylate (CH3ONa) instead of potassium hydroxide (KOH), higher yields in methyl esters, purer products and easier to separate are obtained, since soaps are not formed by hydrolysis.

The sample of test 8 (obtained with CH3ONa and having a conversion at 96%) was analyzed by gas-chromatography and the following results were obtained (percentages by weight):

98.34% methyl esters;

Monoglycerides 1.11%;

Diglycerides 0.2%;

Triglycerides 0.3%

Example 4

In this example the results obtained for the transesterification reaction carried out in a plate reactor 20 at room temperature are reported.

The operating conditions adopted are described in table 9.

Table 9: Conditions used for the transesterification reaction of example 4.

Time

Scope

of Catalyst / oil Oil / methanol Temperature Total catalyst

residence (g / g) (mol / mol) (° C)

(ml / min)

(s)

30 KOH 0.01 400 6 25

We proceeded in the same way as described in the previous examples.

For this reaction a yield in methyl esters equal to 50% was obtained. It is interesting to compare the data obtained with those obtained for the transesterification reaction, carried out under the same operating conditions in a known type microreactor, where the presence of microchannels allows an effective exchange of matter between two immiscible liquid phases, even at low numbers of Reynolds, via the interface between the two.

According to WO 2007/142983, which describes the use of microchannels to produce biodiesel, operating under the same operating conditions a conversion into methyl esters equal to 30% was obtained.

The reactor 20 according to the invention allows, in general, to obtain reactions occurring between two immiscible liquid phases under temperature conditions for which the reaction rate is sufficiently high to take place for contact times between 5 and 600 seconds, preferably between 10 and 60 seconds.

The reactor 20 according to the invention allows, in particular, to produce biodiesel by transesterification of triglycerides with low molecular weight C1-C4 alcohols, preferably methanol and ethanol, in the presence of both acidic and basic Bronsted or Lewis catalysts, preferably NaOH , KOH or related alkoxides, in plate reactors 20 where these plates 24 can be smooth or suitably corrugated with an average distance between the walls that can range from 0.5 to 10 mm, preferably between 1 and 3 mm, operating with fluid flows that they will vary with the volume of the reactor, but such as to generate a turbulent regime in the interspace between one plate and another.

The reactor 20 according to the invention allows to operate in a pressure range between 0.01 and 2.5 MPa, preferably between 0.1 and 1 MPa and at temperatures between 10 ° C and 300 ° C, preferably between 50 ° C and 200 ° C. The plant 1 according to the invention allows the use of both a single plate reactor 20 to make the reaction take place, and a battery of plate reactors 20 placed together in series or in parallel.

The reactor 20 according to the invention allows the use of a heat exchange fluid, in equi or countercurrent, in conditions such as to allow a predetermined temperature profile in the reaction compartment or which guarantees a constant wall temperature.

The reactor 20 according to the invention allows to fill the interspace 28 in which the reaction takes place with inert filling material, of suitable size and of any shape (spheres, flakes, filamentous, etc.) in order to improve the turbulence local.

The reactor 20 according to the invention allows to fill the interspace 28 in which the reaction takes place with active material (which can perform catalytic activity) of suitable size and of any shape (spherical, flaky, filamentous or even membrane-shaped) which has the dual function of improving turbulence and playing a catalytic role.

In conclusion, the plate reactor 20 is surprisingly superior in performance to the reactors and microreactors described with reference to the known art.

To the embodiments of the plate reactor 20 and of the plant 1 described above, the skilled person may, in order to meet specific needs, make modifications and / or replacements of the elements described with equivalent elements, without thereby departing from the scope of the claims attached.

Claims (14)

CLAIMS 1. Reactor (20) for reactions occurring between at least two reactants provided in two liquid phases (12, 13), comprising: - an inlet (21) suitable for receiving the two liquid phases (12, 13); - an output (22) suitable for emitting the products (14); - a channel (23) suitable for receiving a continuous flow of the two liquid phases (12, 13) and / or of the products (14), in which the channel (23) comprises, at least in one section, an interspace (28) enclosed between two plates (24) arranged at a distance of at least 0.5 mm, and in which the channel (23) comprises means (25) for promoting turbulence in the continuous flow of the two liquid phases (12, 13) and / or of the products (14); And wherein the reactor (20) comprises means (26) for generating a heat exchange between the plates (24) and the continuous flow of the two liquid phases (12, 13) and / or of the products (14). Reactor (20) according to claim 1 wherein the plates (24) are arranged at a distance not greater than 10mm, preferably between 1mm and 3mm. Reactor (20) according to claim 1 or 2 wherein the means (25) for promoting turbulence in the continuous flow of the two liquid phases (12, 13) and / or of the products (14) comprise corrugations or knurls of the surface of the plates (24). Reactor (20) according to any preceding claim wherein the means (25) for promoting turbulence in the continuous flow of the two liquid phases (12, 13) and / or of the products (14) comprise filling material comprised between the plates (24). 5. Reactor (20) according to the preceding claim in which the filling material comprised between the plates (24) is suitable for carrying out catalytic activity. Reactor (20) according to any preceding claim wherein the means (26) for generating a heat exchange between the plates (24) and the continuous flow of the two liquid phases (12, 13) and / or of the products (14) they comprise means (4) for heating the plates (24) to a temperature between 10 ° C and 300 ° C, preferably between 50 ° C and 200 ° C. 7. Plant (1) comprising a reactor (20) according to any preceding claim, means (5) for the continuous feeding of the two liquid phases (12, 13) to the reactor (20), and means (6) for the outflow continuous of the products (14) from the reactor (20). 8. Plant (1) according to claim 7 further comprising means (11) for maintaining the pressure inside the plant (1) between 0.01MPa and 2.5MPa, preferably between 0.1Mpa and 1Mpa. Plant (1) according to claim 7 or 8 further comprising means (50) for pre-mixing the two liquid phases (12, 13) upstream of the reactor (20). Plant (1) according to any one of claims 7 to 9 further comprising means (50) for pre-heating the two liquid phases (12, 13) upstream of the reactor (20). 11. Method for obtaining products (14) from a chemical reaction between at least two reactants provided in two liquid phases (12, 13), comprising the steps of: - Feed the two liquid phases (12, 13) to a reactor (20) having a channel-shaped reaction chamber (23) suitable for receiving a continuous flow of the two liquid phases (12, 13) and / or products (14 ), in which the channel (23) comprises, at least in one section, a gap (28) enclosed between two plates (24) arranged at a distance of at least 0.5 mm, and in which the channel (23) comprises means (25 ) to promote turbulence in the continuous flow of the two liquid phases (12, 13) and / or of the products (14); - generating a heat exchange between the plates (24) and the continuous flow of the two liquid phases (12, 13) and / or of the products (14); And - Collect the products (14) at the outlet (22) of the reactor (20). Method according to claim 11 wherein one liquid phase (12) comprises oil and / or fat of vegetable or animal origin, the other liquid phase (13) comprises a light alcohol, the two phases being immiscible with each other, the reaction it is a transesterification and the reaction products (14) include biodiesel and glycerin. 13. Method according to claim 12 wherein said oil of vegetable origin is selected from the group comprising: rapeseed oil, palm oil, sunflower oil, castor oil, soybean oil, cottonseed oil, peanut oil, peanut oil seaweed, jatropa oil (jatropha curcas), and the like; and wherein said light alcohol is ethyl alcohol or preferably methyl alcohol. 14. Method according to claim 12 or 13 further comprising the step of mixing to the two reactants also a basic homogeneous catalyst selected from the group comprising: sodium hydroxide (NaOH), potassium hydroxide (KOH) and corresponding alkoxides with preference for methoxide of sodium (CH3ONa) or sodium ethoxide (C2H5ONa).