FR3097037A1 - Distillation device with improved cooling system - Google Patents

Abstract

Distillation device comprising an improved cooling system The object of the invention is a distillation device which is characterized in that a cooling system (102) provided for cooling the coolant of a refrigerating system (52) comprises a machine adsorption (104). Figure 13

Description

Distillation device comprising an improved cooling system

The present application relates to a distillation device comprising an improved cooling system.

According to one embodiment visible in Figure 1, a distillation device such as a Charentais still comprises a boiler 10 configured to contain a liquid to be distilled, a gas burner 12 arranged under the boiler 10, a fire tower 14 surrounding the boiler and configured to evacuate the burnt gases resulting from the combustion towards an evacuation duct 16, a capital 18 surmounting the boiler 10 at the level of which condensation and reflux phenomena take place, a gooseneck 20 collecting the vapors of alcohol leaving the marquee 18 and conveying them to a coil 22 positioned in a cooling system 24.

The cooling system 24 comprises a tank 26 containing water in which the coil 22 is immersed. The fluids flowing from top to bottom in the coil 22, the cooling system 24 makes it possible to obtain the condensation of the alcohol vapors in the upper part of the coil 22 and the cooling of the distillates in the lower part of the coil 22. As illustrated in Figure 1, the cooling system 24 comprises a cold water supply 24.1 in the lower part of the cooling system 24 and a hot water outlet 24.2 in the upper part of the cooling system 24. The water has a temperature of the order from 7 to 10° C. at the cold water supply 24.1 and a temperature of the order of 80 to 85° C. at the hot water outlet 24.2. Tray 26 of cooling system 24 is open at the top and surmounted by a chimney 28 to evacuate water vapours.

A water cooling system (not shown) is associated with the cooler to allow the water temperature to be reduced to around 8 or 10°C. According to one embodiment, the water cooling system includes a plurality of cooling towers.

According to this embodiment, the distillation requires a significant amount of energy to ensure the operation of the cooling system in order to cool the water in the cooling system 24.

The present invention aims to remedy all or part of the drawbacks of the prior art.

To this end, the subject of the invention is a distillation device comprising a boiler configured to contain a liquid to be distilled, at least one heating system configured to heat the liquid to be distilled contained in the boiler, a collection pipe configured to collect alcohol vapors emanating from the boiler, a cooling system containing a heat transfer fluid, a cooling pipe connected to the collection pipe and immersed in the heat transfer fluid contained in the cooling system and a cooling system for cooling the heat transfer fluid of the refrigerant system.

According to the invention, the cooling system comprises an adsorption machine having first, second and third stages, the first stage comprising a first supply of hot heat transfer fluid coming from the cooling system, the third stage comprising a third outlet connected to the system refrigerant.

The distillation device according to the invention makes it possible to reduce the quantity of energy necessary to cool the heat transfer fluid of the refrigerant system.

According to another characteristic, the first stage comprises a hot heat transfer fluid outlet connected to a storage tank for the warm heat transfer fluid.

According to another characteristic, the cooling system comprises at least one heat exchanger to cool the heat transfer fluid between the outlet and the storage tank of the first stage.

According to another characteristic, the first stage comprises a temperature maintenance loop to maintain the temperature of the heat transfer fluid stored in the storage tank below a set temperature, the temperature maintenance loop being configured to reinject the heat transfer fluid stored in the storage tank upstream of the heat exchanger.

According to another characteristic, the second stage comprises a second supply and a second outlet connected to a cooling loop in which a refrigerant fluid circulates.

According to another characteristic, the third stage comprises a third supply connected to the storage tank for the lukewarm heat transfer fluid of the first stage.

According to another characteristic, the third stage comprises a storage tank and a cold unit through which the heat-transfer fluid goes from the third outlet to the storage tank of the third stage.

According to another characteristic, the third stage comprises a loop configured to reinject the heat transfer fluid stored in the storage tank of the third stage at the level of a three-way valve connecting the storage tank of the first stage and the third supply of the third stage.

Other characteristics and advantages will emerge from the description of the invention which follows, description given by way of example only, with regard to the appended drawings, among which:

is a schematic representation of a distillation device which illustrates an embodiment of the prior art,

is a schematic representation of a distillation device which illustrates one embodiment of the invention,

is a perspective view with a detail of a bi-material plate used to manufacture a boiler which illustrates an embodiment of the invention,

is a perspective view of a bottom of a boiler which illustrates an embodiment of the invention,

is a section with a detail of a bottom of a boiler which illustrates an embodiment of the invention

is a section of part of a boiler which illustrates an embodiment of the invention,

is a section of a boiler part which illustrates another embodiment,

is a section of a boiler part which illustrates another embodiment,

is a schematic representation of a distillation device comprising a heat exchanger between a cooling system and a boiler which illustrates an embodiment of the invention,

is a schematic representation of a distillation device comprising a heat exchanger between a cooling system and a boiler which illustrates another embodiment of the invention,

is a cross section of a gooseneck which illustrates one embodiment of the invention,

is a vertical section of a marquee which illustrates an embodiment of the invention,

is a schematic representation of a coolant cooling system of a refrigerant system which illustrates one embodiment of the invention.

According to different embodiments visible in Figures 2, 9 and 10, a distillation device comprises a boiler 40 configured to contain a liquid to be distilled 42, at least one heating system 44 configured to heat the liquid to be distilled 42, a capital 46 surmounting the boiler 40, a gooseneck 48 configured to collect the alcohol vapors leaving the marquee 46 and route them to a coil 50 positioned in a cooling system 52 containing a first heat transfer fluid.

In operation, the coil 50 comprises a first section 50.1 at which the alcohol vapors condense and a second section 50.2 at the level of which the distillates resulting from the condensation of the alcohol vapors flow and are cooled.

The boiler 40 comprises a bottom 54 and a dome 56 (also called collar) having an opening 58 allowing the interior of the boiler 40 to communicate with the interior of the capital 46.

According to one embodiment, the bottom 54 and the dome 56 each have an approximately half-sphere shape and the boiler 40 comprises an approximately cylindrical side wall 60 inserted between the bottom 54 and the dome 56 and connecting them. By way of example, the bottom 54 has an upper edge 54.1, approximately circular, positioned in a substantially horizontal plane, which has a diameter of between 600 and 2000 mm. Of course, the invention is not limited to this geometry or these dimensions for the boiler 40.

According to an embodiment visible in Figure 5, the bottom 54 comprises at least one wall 62 in contact with the liquid to be distilled 42 in operation.

The wall 62 comprises a first internal layer 62.1 made of a first material chosen for its characteristics suitable for a distillation process and a second external layer 62.2 made of a second material, different from the first material, chosen for its mechanical characteristics; the first and second layers 62.1, 62.2 being intimately linked in order to promote heat transfer between them, as illustrated in FIGS. 3 and 5.

The first internal layer 62.1 is in contact with the liquid to be distilled 42 in operation.

According to one embodiment, the first material is a copper alloy or copper, preferably with a high level of purity of the order of 99.9%. By way of example, the first material can be chosen from the following copper grades: CUB1, CUC1.

According to one embodiment, the second material is a stainless steel, preferably ferromagnetic. For example, the second material can be chosen from the following grades: 304 stainless steel, 316L stainless steel, 410S stainless steel.

According to one configuration, the first internal layer 62.1 has a thickness comprised between 1 and 10 mm, preferably comprised between 1 and 6 mm. The second outer layer 62.2 has a thickness of between 1 and 20 mm, this thickness varying according to the heating system 44.

According to one operating mode, the first internal layer 62.1 is a sheet, sheet or plate, produced in the first material, substantially planar and the second external layer 62.2 is a sheet, sheet or plate, produced in the second material, substantially planar.

According to the invention, a method for manufacturing a wall 62 comprises a first step of plating by vacuum explosion, also called "cladding" in English, to obtain a metallurgical bond between the internal and external layers 62.1, 62.2 which do not form more than a single piece in the form of a substantially flat metal composite wall 63, visible in Figure 3.

The fact that the first and second layers 62.1, 62.2 are initially flat facilitates the explosion plating operation. At the end of this operation, a homogeneous surface contact is obtained over the entire surface of the first and second layers 62.1, 62.2 guaranteeing an optimal heat transfer by conduction between said first and second layers 62.1, 62.2.

The method of manufacturing a wall 62 also comprises a step of shaping the metal composite wall 63 in order to obtain the wall 62. This shaping step can be obtained by cold or hot stamping according to the thickness of the second layer 62.2 and/or by any other method of deformation.

The plating operation by vacuum explosion makes it possible to avoid delamination between the first and second layers 62.1, 62.2 during the shaping step. To avoid any phenomenon of delamination, the wall 62 generally has a geometry which does not include an excessively small radius of curvature.

According to this manufacturing process, the wall 62 comprises an internal copper face which makes it possible to obtain the desired organoleptic characteristics and certain chemical interactions with the liquid to be distilled 42, as with the boilers of the prior art entirely made of copper. The fact that the wall 62 is made of bi-material makes it possible, at equal thickness, to obtain mechanical characteristics superior to a wall 62 made of copper mono-material. Finally, the explosion plating operation makes it possible to obtain first and second layers 62.1, 62.2 intimately linked guaranteeing optimal heat transfer between said first and second layers 62.1, 62.2.

According to one embodiment, the bottom 54 and the side wall 60 each comprise a wall 62 which has a first layer 62.1 of a first material, such as copper for example, in contact with the liquid to be distilled 42 in operation, and a second layer 62.2 in a second material, such as stainless steel for example.

According to another embodiment, only the bottom 54 comprises a wall 62 which has a first layer 62.1 in a first material, such as copper for example, in contact with the liquid to be distilled 42 in operation, and a second layer 62.2 in a second material, such as stainless steel for example. According to another embodiment, only the side wall 60 comprises a wall 62 which has a first layer 62.1 in a first material, such as copper for example, in contact with the liquid to be distilled 42 in operation, and a second layer 62.2 in a second material, such as stainless steel for example.

According to one embodiment visible in Figure 6, the distillation device comprises several heating systems 44 of different natures, such as for example a first heating system 44 using at least a second heat transfer fluid and a second heating system 44 'using at least one magnetic field. According to one configuration, the first heating system 44 using a second heat transfer fluid is provided at the level of the bottom 54 and the second heating system 44' using at least one magnetic field is provided at the level of the side wall 60.

Of course, the invention is not limited to this arrangement. Thus, the boiler 40 could include other heating systems, such as for example a gas burner. It could comprise a single heating system or several heating systems of the same type, as illustrated in FIG. 7. However, the fact of providing several heating systems of different types, using different physical principles, makes it possible to obtain a mode optimized operation.

According to one embodiment visible in Figures 6 and 8, the heating system 44 'using at least a magnetic field comprises at least one inductor, such as for example a coil wound around the boiler 40, in particular around the side wall 60 or positioned at the bottom 54.

According to one embodiment visible in Figures 6 and 7, the heating system 44 using a second heat transfer fluid comprises at least one pipe 64 pressed against the wall 62, a power supply 66.1 to supply second hot heat transfer fluid to the heating system 44 and an outlet 66.2 to evacuate the second cooled heat transfer fluid. According to one configuration, the pipe 64 is in the form of a coil-type heat exchanger, in which the second pressurized heat transfer fluid circulates, pressed against the outer face of the wall 62, connected at a first end to a power supply 66.1 and at a second end to an output 66.2.

According to Figure 8, the boiler 40 is of the double wall type and comprises a first bi-material wall 62 which extends at the level of the bottom 54 and the side wall 60 as well as a second wall 68 spaced from the first wall 62 so as to define a cavity 70 containing the second heat transfer fluid and having at least one supply for supplying the heating system 44 with the second hot heat transfer fluid and an outlet for discharging the cooled second heat transfer fluid. The first and second walls 62, 68 form a double envelope containing the second heat transfer fluid under pressure.

According to one embodiment, the bottom 54 comprises a second wall 68 spaced from the first wall 62 and a peripheral junction wall 72 connecting the first and second walls 62 and 68 in a sealed manner. The first and second walls 62, 68 as well as the peripheral junction wall 72 delimit a cavity 70 in which circulates a second heat transfer fluid, such as for example steam, pressurized water, superheated water or pressurized gas.

The bottom 54 can comprise partitions or stiffeners positioned in the cavity 70, connecting the first and second walls 62 and 68 so as to limit the risks of deformation of said walls 62, 68 and/or so as to define a flow path for the second heat transfer fluid between a supply and a fluid outlet.

The second wall 68 positioned outside is made of stainless steel.

According to one application, the heat transfer fluid is a pressurized fluid, the first and second walls 62, 68 and their assembly being configured to ensure the absorption of the forces associated with a pressure greater than 3 bars in the cavity 70, preferably between 0 and 20 bar. For example, in the case of steam, the pressure will be around 3 bars and in the case of gas, it may reach 15 bars depending on the type of gas.

Of course, the double wall is not limited to the bottom 54. Thus, the side wall 60 could comprise first and second walls 62, 68 delimiting a cavity 70 containing a second heat transfer fluid.

The boiler 40 can comprise a single heating system 44, several heating systems of the same type, several heating systems of different types, the heating system(s) being able to be positioned only at the level of the bottom 54 or at the level of the bottom 54 and the side wall 60 or only at the level of the side wall 60.

According to one embodiment, the boiler 40 comprises at least one thermal insulator configured to insulate the boiler 40 in order to limit heat losses. Thus, the quantity of heat transferred between each heating system 44 and the liquid to be distilled 42 is optimized.

According to one embodiment, the boiler 40 comprises a supply 74 of liquid to be distilled 42 and a drain 76.

According to a feature of the invention, the first coolant of the refrigerant system 52 is used to heat the boiler 40, as illustrated in Figure 2.

The distillation device comprises at least one heat exchanger 78 to ensure heat exchange between the first heat transfer fluid of the cooling system 52 and the second heat transfer fluid of a heating system 44 of the boiler 40.

According to one embodiment visible in Figures 9 and 10, the exchanger 78 comprises a very high temperature heat pump having, in the direction of circulation of a refrigerant, an evaporator in which circulates the first heat transfer fluid of the system refrigerant 52, a compressor which increases the pressure and the heat of the refrigerant, a condenser in which the second heat transfer fluid circulates and an expansion valve which decreases the pressure.

1. un premier circuit isolé thermiquement dans lequel s’écoule le premier fluide caloporteur reliant :
   1. une première entrée 80.1 de l’échangeur 78 et une sortie 52.1 du système réfrigérant 52 au niveau de laquelle s’écoule le premier fluide caloporteur à une température comprise entre 85 et 100°C,
   2. une première sortie 80.2 de l’échangeur 78 et un retour 52.2 du système réfrigérant 52 au niveau de laquelle s’écoule le premier fluide caloporteur à une température comprise entre 70 et 85°C,
2. un deuxième circuit isolé thermiquement dans lequel s’écoule le deuxième fluide caloporteur reliant :
   1. une deuxième sortie 82.1 de l’échangeur 78 et une alimentation 66.1 du système de chauffe 44 au niveau de laquelle s’écoule le deuxième fluide caloporteur à une température comprise entre 110°C et 150°C,
   2. une deuxième entrée 82.2 de l’échangeur 78 et une sortie 66.2 du système de chauffe 44 au niveau de laquelle s’écoule le deuxième fluide caloporteur à une température comprise entre 90 et 130°C.

The distillation device includes:

1. a first thermally insulated circuit in which flows the first heat transfer fluid connecting:
   1. a first inlet 80.1 of the exchanger 78 and an outlet 52.1 of the refrigerating system 52 at the level of which the first heat transfer fluid flows at a temperature between 85 and 100°C,
   2. a first outlet 80.2 from the exchanger 78 and a return 52.2 from the cooling system 52 at which the first heat transfer fluid flows at a temperature between 70 and 85°C,
2. a second thermally insulated circuit in which flows the second heat transfer fluid connecting:
   1. a second outlet 82.1 from the exchanger 78 and a supply 66.1 from the heating system 44 at the level of which the second heat transfer fluid flows at a temperature between 110° C. and 150° C.,
   2. a second inlet 82.2 of the exchanger 78 and an outlet 66.2 of the heating system 44 at the level of which the second heat transfer fluid flows at a temperature between 90 and 130°C.

According to one embodiment, the first and second heat transfer fluids are water. The very high temperature heat pump has a coefficient of performance greater than 3. The first circuit and/or the second circuit comprises at least one circulation pump 84.

According to the invention, the heat recovered during the condensation of the alcohol vapors and/or released during the cooling of the distillates in the coil 50 is used to heat the liquid to be distilled 42 in the boiler 40. The use of a heat pump increases the amount of heat returned to the heating system 44 compared to the amount of heat extracted from the cooling system 52.

In one configuration, with alcohol vapors and distillates flowing from top to bottom in coil 50, outlet 52.1 is positioned higher than return 52.2.

According to one characteristic, the cooling system 52 comprises a closed reservoir 86, containing the first heat transfer fluid, which has a first orifice 87.1 in the upper part to allow the passage of a section of duct from the gooseneck 48 connected to an upstream end of the coil 50 and a second orifice 87.2 in the lower part through which a downstream end of coil 50 passes.

This reservoir 86 comprises a partition 88 dividing it into an upper chamber 86.1 positioned above the partition 88 and a lower chamber 86.2 positioned below the partition 88, the latter being crossed by the coil 50.

According to one embodiment, at least the upper chamber 86.1 is insulated. According to another embodiment, the entire tank 86 is insulated.

According to one configuration, the partition 88 is positioned relative to the coil 50 so that the first section 50.1 of the coil 50 at which the alcohol vapors condense is positioned above the partition 88 and the second section 50.2 of the coil 50 is positioned below partition 88.

According to one configuration, the first heat transfer fluid used in the exchanger 78 is that present in the upper chamber 86.1. Thus, the tank 86 has an outlet 52.1 of the first heat transfer fluid connected to the heat exchanger 78 opening in the upper part of the upper chamber 86.1 and a return 52.2 of the first heat transfer fluid connected to the heat exchanger 78 opening in the lower part of the superior room 86.1.

The fact of providing a tank 86 closed and insulated at least at the level of the upper chamber 86.1 limits the heat losses and the evaporation of the first heat transfer fluid, which leads to optimizing the collection of the latent heat produced during the condensation of the vapors of alcohol and used for heating boiler 40.

The presence of the partition 88 makes it possible to split the first heat transfer fluid into two volumes; a first volume, present in the upper chamber 86.1 and circulating in the first circuit, used to cause the condensation of the alcohol vapors, to collect the heat produced by this condensation and to transfer it to the exchanger 78 as well as a second volume, present in the lower chamber 86.2, used to cool the distillate circulating in the second section of the coil 50.

The fact of providing a partition 88 makes it possible to avoid the mixing of the coolant in the lower chamber 86.2 due to the return 52.2 of the first coolant in the upper chamber 86.1.

As for the prior art, the gooseneck 48 includes a duct 90 to channel the alcohol vapors, which extends from the marquee 46 to the coil 50 and which passes through the reservoir 86. This duct 90 can pass through a heater wine (not shown).

According to a feature of the invention visible in Figures 10 and 11, the gooseneck 48 comprises, in addition to the conduit 90, a thermal insulator 92 which surrounds the conduit 90 over at least a certain length from the capital 46 to the tank 86, with the exception of the possible section of conduit 90 positioned in the wine warmer. According to the configuration visible in Figure 10, the thermal insulation 92 extends from the capital 46 to the reservoir 86.

The presence of the thermal insulation 92 makes it possible to limit the heat losses at the level of the gooseneck 48. Thus, the heat losses which appeared at the level of the gooseneck 48 in the devices of the prior art are transferred into the tank 86 and transmitted to the first heat transfer fluid.

For certain distillation processes, a rectification phenomenon is produced in the gooseneck 48. In this case, at least a part of the gooseneck 48, in particular that close to the capital 46, before the high point of the gooseneck 48, is thermoregulated and the thermal insulation 92 is associated with a cooling system 93. According to one configuration, the cooling system 93 uses the first heat transfer fluid which is taken from the upper chamber 86.1 at a given height, depending on the desired temperature . After its use for cooling the thermoregulated part of the gooseneck 48, the first heat transfer fluid is reinjected into the upper chamber 86.1 because it has a higher temperature than that which it presented when it was taken. Consequently, this cooling system contributes to bringing calories into the upper chamber 86.1, as symbolized by the arrow 93 in FIG. 10. A circulator can be used to modulate the contact time of the first heat transfer fluid with the part of the neck of swan 48 thermoregulated.

Finally, the thermoregulation of the gooseneck 48 can use another heat transfer fluid, independent of the cooling system 52.

According to one embodiment visible in Figure 12, the capital 46 comprises at least one cavity 94 communicating, in the lower part, with the boiler 40 and, in the upper part, with the gooseneck 48. This cavity 94 is delimited by a envelope 96. The geometry and the dimensions of the envelope 96 are not further described because they vary according to the desired condensation and reflux phenomena. They may be identical to those of the capitals of the prior art.

Generally, this casing 96 is made of copper or a copper alloy.

According to a particularity of the invention illustrated by FIG. 12, the marquee 46 is thermoregulated and comprises, in addition to the envelope 96, at least one system for regulating the temperature of the envelope 96. According to one embodiment, the marquee 46 comprises at least one cooling system 98 for the envelope 96. According to one configuration, each cooling system 98 is pressed against the envelope 96, the assembly being covered with a thermal insulator 100 to limit heat loss .

By way of example, the marquee 46 may include at least one cooling system 98 configured to cool at least one zone of the envelope 96.

The fact that the marquee 46 is thermoregulated makes it possible to better control the phenomena of condensation and/or reflux inside the marquee 46.

According to one embodiment, the marquee 46 comprises at least one cooling system 98 using a heat transfer fluid. The first heat transfer fluid present in the cooling system 52 can be used to regulate the temperature of the enclosure 96 of the tent 46.

According to another feature, the dome 56 is thermoregulated in order to better control the phenomena of condensation and/or reflux, in the same way as the capital 46.

Whatever the thermoregulated zone, the reservoir 86 can have several tappings 99 at different heights from the upper chamber 86.1 to take the first heat transfer fluid at different temperatures.

Thus, according to one characteristic of the invention, the capital 46 and/or at least part of the gooseneck 48 and/or the dome 56 of the boiler 40 are insulated and/or thermoregulated.

As illustrated in FIG. 2, the distillation device comprises a cooling system 102 for cooling the first heat transfer fluid of the cooling system 52. This cooling system 102 comprises an inlet 102.1 connected to an outlet 104.1 of the cooling system 52 and an outlet 102.2 connected to a return 104.2 of the refrigerant system 52.

When the cooling system 52 comprises a tank 86 equipped with a partition 88, the first heat transfer fluid cooled by the cooling system 102 is present in the lower chamber 86.2 of the tank. According to this configuration, the return 104.2 and the outlet 104.1 of the cooling system 52 emerge respectively in the lower part and in the upper part of the lower chamber 86.2.

According to a feature of the invention, the cooling system 102 uses adsorption cooling. This solution makes it possible to reduce the amount of energy needed to cool the heat transfer fluid of the refrigerant system 52.

According to an embodiment visible in Figure 13, the cooling system 102 comprises an adsorption machine 104 which has first, second and third stages 106, 108, 110.

The first stage 106 comprises a first supply 106.1 of hot heat transfer fluid coming directly from the cooling system 52 or from a first storage tank 112 for hot heat transfer fluids coming from several cooling systems 52. The first stage 106 can include a buffer tank 114 in upstream of the first supply 106.1. By way of indication, the first heat transfer fluid has a temperature of between 70° C. and 100° C. at the level of the first supply 106.1.

The first stage 106 also includes a hot heat transfer fluid outlet 106.2 connected to a second storage tank 116 for the warm heat transfer fluid. Between the outlet 106.2 and the second storage tank 116, the cooling system 102 comprises at least one heat exchanger 118, 118' to cool the heat transfer fluid. According to one configuration, the cooling system 102 comprises a first plate exchanger 118 connected to a geothermal loop and/or a second plate exchanger 118' connected to a loop comprising at least one air cooler 120 or any other cold source. As an indication, the lukewarm heat transfer fluid stored in the second storage tank 116 has a temperature of around 20°C. According to one embodiment, the second storage tank 116 comprises an auxiliary supply 122 of heat transfer fluid. The first stage 106 can include a temperature maintenance loop 124 to maintain the temperature of the heat transfer fluid stored in the second storage tank 116 below a set temperature. The temperature maintenance loop 124 is configured to reinject the heat transfer fluid stored in the second storage tank 116 upstream of at least one of the heat exchangers 118, 118'.

The second stage 108 comprises a second supply 108.1 and a second outlet 108.2 connected to a cooling loop 126 in which a refrigerant fluid circulates, said cooling loop 126 having a pump 128 and a heat exchanger 130 connected to at least one air cooler 132 or any other cold source.

The third stage 110 comprises a third supply 110.1 connected to the second storage tank 116 of the warm heat transfer fluid and a third outlet 110.2 directly connected to at least one cooling system 52 or to a third storage tank 134 of the cold heat transfer fluid connected to at least one least one cooling system 52. As an indication, the temperature of the cold heat transfer fluid stored in the third storage tank 134 is of the order of 8°C.

According to one embodiment, the third stage 110 comprises a cold unit 136 through which the heat transfer fluid goes from the third outlet 110.2 to the third storage tank 134.

According to one configuration, the third storage tank 134 comprises an auxiliary supply 138 of heat transfer fluid. The third stage 110 may include a loop 140 to maintain the temperature of the heat transfer fluid stored in the third storage tank 134 below a set temperature. The loop 140 is configured to reinject the heat transfer fluid stored in the third storage tank 134 at the level of a three-way valve 142 connecting the second storage tank 116 and the third supply 110.1 of the third stage 110.

The loop 140 makes it possible to make a mixture between the lukewarm water of the second storage tank 116 and the cold water of the third storage tank 134, via the valve 142, to bring into the third stage 110 a controlled temperature at the around 13°C. The third stage 110 will make it possible to go down to around 8°C and, in the event that the 8°C is not respected, the cold unit 136 makes it possible to achieve this.

The cooling system 102 is not limited to the embodiment visible in Figure 13. Thus, the heat transfer fluid could pass through the second stage 108 between the outlet of the first stage 106 and the second storage tank 116.

Whatever the embodiment, the first heat transfer fluid by crossing the first and third stages 106, 110 of the adsorption machine 104 and possibly its second stage 108 can be cooled to a hot temperature of the order of 80° C to a cold temperature of around 8°C.

According to one embodiment visible in Figure 10, the distillation device comprises a bypass system 144 of the refrigerant system 52 and a start loop 146. According to one configuration, the bypass system 144 comprises a first valve three channels 148 which has a first inlet 148.1 connected to the outlet 52.1 of the refrigeration system 52, a second inlet 148.2 and an outlet 148.3 connected to the pump 84 or to the first inlet 80.1 of the exchanger 78 as well as a second three-way valve 150 which has an inlet 150.1 connected to the first outlet 80.2 of the exchanger 78 or to an inertia tank 152, a first outlet 150.2 connected to the return 52.2 of the cooling system 52 and a second outlet 150.3 connected to the second inlet 148.2 of the first three-way valve 148 via a bypass conduit 154. The start loop 146 comprises a second heat exchanger 156 configured to ensure heat exchanges between the first heat transfer fluid and the second heat transfer fluid or the pressurized gas of the exchanger 78. The second heat exchanger 156 has, for the first heat transfer fluid, a first inlet 156.1 connected to a third three-way valve 158 inserted between the first three-way valve 148 and the exchanger 78 as well as a first outlet 156.2 connected to a fourth three-way valve 160 inserted between the third three-way valve 158 and, for the second heat transfer fluid, a second inlet 156.3 connected to the second outlet 82.1 of the exchanger 78 as well as a second outlet 156.4 connected to the supply 66.1 of the system heater 44.

The first and second three-way valves 148, 150 are configured to occupy a first state in which they communicate the first exchanger 78 and the refrigerant system 52 as well as a second state in which they short-circuit the refrigerant system 52. The third and fourth three-way valves 158, 160 are configured to occupy a first state in which they bypass the second exchanger 156 and a second state in which they allow the first heat transfer fluid to pass through the second exchanger 156.

The operating principle of the distillation device is as follows:

A liquid to be distilled 42 is introduced into the boiler 40. Initially, this liquid to be distilled 42 is brought to a boil to start the evaporation process. This rise in temperature can be achieved using a heating system independent of the first heat transfer fluid, such as for example a heating system 44′ using at least one magnetic field.

According to another operating mode illustrated by FIG. 10, this rise in temperature is obtained by using the first heat transfer fluid. In this case, as long as the liquid to be distilled is not brought to a boil, the first and second three-way valves 148, 150 occupy the second state, bypassing the refrigerant system 52, and the third and fourth three-way valves 158 , 160 occupy the second state allowing the first heat transfer fluid to pass through the second exchanger 156. This configuration makes it possible to initiate the heating of the liquid to be distilled 42 contained in the boiler 40 until it boils.

When the liquid to be distilled 42 is brought to a boil, the alcohol vapors escaping from the boiler 40 and crossing the capital 46 are collected by the gooseneck 48 and conveyed to the coil 50. In the coil 50, the vapors of alcohol condense in the first section 50.1 of the coil 50 then the distillates are cooled in the second section 50.2 of the coil 50.

The condensation of the alcohol vapors generates latent heat captured by the first heat transfer fluid contained in the upper chamber 86.1 of the reservoir 86 of the cooling system 52 and used to heat the boiler 40 via a very high heat pump. temperature.

The cooling of the distillates generates sensible heat captured by the first heat transfer fluid contained in the lower chamber 86.2 of the reservoir 86 of the cooling system 52. The first heat transfer fluid contained in the lower chamber 86.2 is cooled by the cooling system 102 using cooling by adsorption.

When the temperature of the first heat transfer fluid reaches a certain threshold allowing the operation of the exchanger 78, the first and second three-way valves 148, 150 are switched to the first state so that the refrigerant system 52 communicates with the exchanger 78, then the third and fourth three-way valves 158, 160 are switched to the first state, bypassing the second exchanger 156.

The distillation device of the invention makes it possible to recover the energy generated by the condensation of the alcohol vapors in the cooling system 52 which was lost in the distillation devices of the prior art and which is used to heat the boiler 40 according to the invention.

The distillation device makes it possible to reduce the quantity of first heat transfer fluid to be cooled following the cooling of the distillates in the cooling system 52, which makes it possible to reduce the quantity of energy necessary for cooling the first heat transfer fluid. The use of a cooling system using adsorption cooling also reduces the amount of energy needed to cool the first heat transfer fluid.

Although described applied to a Charentais still, the invention is in no way limited to this type of still. Whatever the embodiment, the distillation device comprises a boiler 40 containing a liquid to be distilled 42, a collection conduit configured to collect alcohol vapors emanating from the boiler 40, a cooling system 52 containing a first heat transfer fluid , a cooling conduit connected to the collection conduit and immersed in the first heat transfer fluid contained in the cooling system 52. According to the embodiment illustrated by FIG. 2, the collection conduit comprises a capital 46 as well as a gooseneck 48 and the cooling duct corresponds to coil 50.

Claims (8)

Distillation device comprising a boiler (40) configured to contain a liquid to be distilled (42), at least one heating system (44) configured to heat the liquid to be distilled (42) contained in the boiler (40), a collector (46, 48) configured to collect alcohol vapors emanating from the boiler (40), a cooling system (52) containing a heat transfer fluid, a cooling conduit (50) connected to the collection conduit (46, 48) and immersed in the heat transfer fluid contained in the cooling system (52) and a cooling system (102) for cooling the heat transfer fluid of the cooling system (52), characterized in that the cooling system (102) comprises a machine adsorption unit (104) having first, second and third stages (106, 108, 110), the first stage (106) comprising a first supply (106.1) of hot heat transfer fluid coming from the cooling system (52), the third stage (110) comprising a third outlet (110.2) connected to the cooling system (52). Distillation device according to Claim 1, characterized in that the first stage (106) comprises an outlet (106.2) for hot heat transfer fluid connected to a storage tank (116) for warm heat transfer fluid. Distillation device according to the preceding claim, characterized in that between the outlet (106.2) and the storage tank (116) of the first stage (106), the cooling system (102) comprises at least one heat exchanger (118, 118') to cool the heat transfer fluid. Distillation device according to the preceding claim, characterized in that the first stage (106) comprises a temperature maintenance loop (124) to maintain the temperature of the heat transfer fluid stored in the storage tank (116) below a set temperature , the temperature maintenance loop (124) being configured to reinject the heat transfer fluid stored in the storage tank (116) upstream of the heat exchanger (118, 118'). Distillation device according to one of the preceding claims, characterized in that the second stage (108) comprises a second supply (108.1) and a second outlet (108.2) connected to a cooling loop (126) in which a refrigerant fluid circulates . Cooling device according to one of the preceding claims, characterized in that the third stage (110) comprises a third supply (110.1) connected to the storage tank (116) for the warm heat transfer fluid of the first stage (106). Cooling device according to the preceding claim, characterized in that the third stage (110) comprises a storage tank (134) and a cold unit (136) through which the heat transfer fluid passes from the third outlet (110.2) to the storage tank. storage (134) of the third stage (110). Cooling device according to the preceding claim, characterized in that the third stage (110) comprises a loop (140) configured to reinject the heat transfer fluid stored in the storage tank (134) of the third stage (110) at the level of a three-way valve (142) connecting the storage tank (116) of the first stage (106) and the third supply (110.1) of the third stage (110).