FR3123716A1 - Fluid Condition Management System - Google Patents

Abstract

Title: Fluid Condition Management System. The main object of the present invention is a system for managing (1) the state of a first fluid (4) contained in a first tank (2) and the state of a second fluid (8) contained in a second tank (6), the first fluid (4) having a boiling temperature lower than a boiling temperature of the second fluid (8) at identical pressure, the management system (1) comprising at least a first line (12 ) intended to be traversed by the first fluid (4) taken in the gaseous state from the first tank (2) and which extends between a gas inlet (26) configured to open onto the first tank (2) to a heat exchange member (38, 40, 42) configured to condense the first fluid (4), the first line (12) comprising at least a first compression member (14a) and a second compression member (14b ), the management system (1) comprising a second line (16) intended to be traversed by the first fluid (4) in the liquid state and/or in the two-phase state that and which extends from the heat exchange member (38, 40, 42) to a second orifice (65) configured to open onto the first tank (2), the management system (1 ) comprising at least one cooling line (18) which extends from the second line (16) to the first line (12) and intended to be traversed by the first fluid (4), the cooling line (18) being connected to the first line (12) between the first compression member (14a) and the second compression member (14b), the management system (1) comprising at least one management line (20) of the state of the second fluid (8) intended to be traversed by the second fluid (8), characterized in that the management system (1) comprises at least one cooling unit (24) for the second fluid (8) circulating in the management line ( 20), the cold generated by the cooling unit (24) resulting from evaporation of the first fluid (4) circulating in the cooling line (18). Figure 1.

Description

Fluid condition management system

The present invention relates to the field of ships using, storing and/or transporting natural gas and/or liquefied petroleum gas, and more particularly falls within the field of systems for managing the state of natural gas and/or of liquefied petroleum gas transported on such ships.

Such ships conventionally comprise tanks which contain natural gas in the liquid state and/or petroleum gas in the liquid state. Such ships can for example contain a first tank dedicated to the storage of a natural gas in liquid form and a second tank dedicated to the storage of a petroleum gas in liquid form. Such ships can transport on the one hand a first petroleum gas contained in a first tank and a second petroleum gas contained in a second tank, the first petroleum gas being different from the second petroleum gas, by its composition for example. In other words, such ships can transport a first fluid which can be liquid natural gas or liquid petroleum gas and a second fluid different from the first fluid and which can be liquid natural gas or liquid petroleum gas.

Natural gas is liquid for example at temperatures below -160°C at atmospheric pressure. These tanks are never perfectly thermally insulated so that the natural gas evaporates there at least partially. Thus, these tanks include both natural gas in a liquid form and in a gaseous form, the latter form of natural gas also being called "BOG" from the acronym "Boil-Off Gas" and accumulates in a tank sky. The pressure of this tank top must be controlled so as not to damage the tank.

Petroleum gas has a boiling point generally between 0°C and -50°C at atmospheric pressure and depending on its composition. Petroleum gas also tends to evaporate at least partially when stored in a tank, and the pressure in the top of the tank generated by the evaporated petroleum gas must also be controlled so as not to damage the tank.

Generally, such vessels are equipped with systems for managing the state of the first and second fluids in order to limit the evaporation of each of these fluids in the tank top. It is understood from this that, for example, these management systems are configured to liquefy on the one hand the first fluid, and on the other hand the second fluid independently of the reliquefaction of the first fluid.

However, each of the management systems generally comprises members for compressing the first evaporated fluid and/or the second evaporated fluid capable of increasing the pressure of said gases. These compression members are generally bulky, the management systems requisitioning a surface area and/or a large volume on the ship.

Furthermore, and for reasons of redundancy, it is customary to add an additional thermal regulation circuit, further increasing the surface and/or volume requisitioned by the management system on the ship. The addition of this additional thermal regulation circuit also entails an additional cost to the cost already necessary for the installation and use of the rest of the management system.

The present invention aims to reduce the space occupied by these compression members in order to reduce the volume requisitioned and the energy consumed by these management systems, and for this purpose proposes a system for managing the state of the first evaporated fluid making it possible to cool also the second fluid in the liquid state, thus reducing the technical means implemented to manage the state of the second fluid as well as the financial impact due to the installation of such a state management system.

The main object of the present invention is a system for managing the state of a first fluid contained in a first tank and the state of a second fluid contained in a second tank, the first fluid having a boiling temperature lower than a boiling temperature of the second fluid at identical pressure, the management system comprising at least a first line intended to be traversed by the first fluid withdrawn in the gaseous state from the first tank and which extends between an inlet configured to open onto the first vessel to a heat exchange member configured to condense the first fluid, the first line comprising at least a first compression member and a second compression member, the management system comprising a second line intended to be traversed by the first fluid in the liquid state and/or in the diphasic state and which extends from the heat exchange member to a second orifice configured to open onto the first tank, the management system comprising at least one cooling line which extends from the second line to the first line and intended to be traversed by the first fluid, the cooling line being connected to the first line between the first compression member and the second compression member, the management system comprising at least one line for managing the state of the second fluid intended to be traversed by the second fluid, characterized in that the management system comprises at least a unit for cooling the second fluid circulating in the management line, the cold generated by the cooling unit resulting from evaporation of the first fluid circulating in the cooling line.

According to an optional arrangement, the management system comprises the first fluid and the second fluid, in particular in that it is traversed by these fluids.

The management system ensures the control of the state of the first fluid and of the second fluid contained respectively in the first tank and in the second tank, that is to say at least the pressure and/or the temperature of the first fluid or the second fluid. The second fluid circulating in the management line is cooled by the cooling unit, the temperature of the second fluid circulating in the management line downstream of the cooling unit being lower than the temperature of the first fluid circulating in the cooling downstream of the cooling unit. This has the effect of lowering the temperature of the second fluid contained in the second tank, thus limiting the evaporation of the second fluid present in the second tank. Furthermore, the second evaporated fluid circulating in the second tank can also be cooled and condense by coming into contact with the second cooled fluid circulating in the management line downstream of the cooling unit and/or by also coming into contact with the second fluid projected into the tank.

The cold used to lower the temperature of the second fluid circulating in the management line comes from the evaporation of part of the first fluid circulating in the cooling line. More precisely, this part of the first fluid is expanded, that is, the pressure of this part of the first fluid is lowered, so that it lowers the temperature of the second fluid.

The first fluid and the second fluid are for example petroleum gas, the first fluid being for example a mixture composed of 92% propane and 8% butane and which has a boiling point of -47°C at pressure atmospheric, while the second fluid is for example composed of approximately 100% butane which has a boiling point of 0° C. at atmospheric pressure.

According to another exemplary embodiment of the invention, the first fluid is for example natural gas such as methane and has a boiling point of approximately -160° C., that is to say that the first fluid is in liquid form when it has a temperature below -160°C at atmospheric pressure.

Furthermore, the condensation of the first fluid in the first line takes place by heat exchange between the first fluid and a cooling fluid at the level of the heat exchange member.

According to an optional characteristic of the invention, the cooling unit comprises at least one heat exchanger and an expansion member installed on the cooling line between the second line and the heat exchanger, the heat exchanger being configured to implement a heat exchange between the first fluid circulating in the cooling line and the second fluid circulating in the management line.

More precisely, the first fluid circulating in the cooling line is expanded by the expansion device before circulating in the heat exchanger. When it crosses the heat exchanger, the second fluid circulating in the management line gives up calories to the expanded first fluid circulating in the cooling line and also crossing the heat exchanger.

In other words, the first fluid circulating in the cooling line and passing through the heat exchanger is heated and evaporated in the heat exchanger by capturing calories from the second fluid circulating in the management line. The first heated and evaporated fluid is then sucked up by one of the compression units installed on the first line.

Furthermore, it is within the heat exchanger that the temperature of the second fluid circulating in the management line decreases to approach the temperature of the first fluid circulating in the cooling line, in particular by the transmission of calories from the second fluid circulating in the management line to the first fluid circulating in the cooling line. It is understood that the temperature of the second fluid circulating in the management line is lowered during the exchange of calories carried out in the heat exchanger.

According to an optional characteristic of the invention, the heat exchanger comprises at least a first pass constituting the cooling line and a second pass constituting the management line, the expansion member being arranged between the second line and the first pass.

It is understood in this configuration that the pressure of the first fluid circulating in the cooling line is lowered by the expansion device, before circulating in the first pass of the heat exchanger.

According to an optional characteristic of the invention, the management system comprises at least one pumping device arranged on the management line upstream of the cooling unit. The pumping member is configured to force the circulation of the second fluid through the management line.

According to an optional characteristic of the invention, the management system comprises at least one pipe extending between the second line and the first line, the pipe being connected on the first line between the first compression member and the second compression member , the management system comprising at least one device for cooling the first fluid circulating in the second line, the cold generated by the cooling device resulting from evaporation of the first fluid circulating in the pipe.

The cold used to lower the temperature of the first fluid circulating in the second line comes from the evaporation of part of the first fluid circulating in the pipe. More precisely, this part of the first fluid is expanded, that is to say that the pressure of this part of the first fluid is lowered, so that it lowers the temperature of the first fluid circulating in the second line.

According to an optional characteristic of the invention, the cooling device comprises at least one heat exchanger and an expansion device, the heat exchanger comprising a first passage constituting the second line and a second passage constituting the pipe, the device for expansion being disposed on the pipe between the second line and the second passage, the heat exchanger being configured to implement a heat exchange between the first fluid flowing in the second line and the first fluid flowing in the pipe.

More precisely, the first fluid circulating in the pipe is expanded by the expansion device before circulating in the heat exchanger. When it passes through the heat exchanger, the first fluid circulating in the second line gives up calories to the expanded first fluid circulating in the pipe during its passage through the heat exchanger.

In other words, the first fluid circulating in the pipe and passing through the heat exchanger is heated and evaporated in the heat exchanger by capturing calories from the first fluid circulating in the second line. The first heated and evaporated fluid is then sucked up by one of the compression units installed on the first line.

Furthermore, it is within the heat exchanger that the temperature of the first fluid circulating in the second line decreases and to approach the temperature of the first fluid circulating in the pipe, in particular by the transmission of the calories of the first fluid circulating in the second line to the first fluid flowing in the pipe.

According to an optional feature of the invention, the management system comprises at least a first heat exchange member between the first fluid and a cooling fluid and a second heat exchange member between the first fluid and the cooling fluid. cooling, the first heat exchange member being installed between the first compression member and the second compression member, the pipe being connected to the first line between the first heat exchange member and the second compression member. The first fluid in the gaseous state circulating in the pipe is mixed with the first fluid in the gaseous state circulating in the first line at a point located between the first heat exchange member and the second compression member.

According to an optional feature of the invention, the cooling line is connected to the pipe between the first line and the cooling device. It is understood that the first fluid in the gaseous state circulating in the cooling line is mixed with the first fluid in the gaseous state circulating in the pipe after having passed through the cooling device.

According to an optional characteristic of the invention, the management system comprises a bifurcation between the second line and the cooling line installed between the second orifice arranged in the first tank and the cooling device.

According to an optional characteristic of the invention, the management system comprises a first device for cooling the first fluid circulating in the second line and a second device for cooling the first fluid circulating in the second line, the management system comprising a bifurcation between the second line and the cooling line installed downstream of the second cooling device.

According to an optional characteristic of the invention, the management system comprises a bifurcation between the second line and the cooling line installed between the second compression member and the cooling device.

According to an optional characteristic of the invention, the management system comprises a first device for cooling the first fluid circulating in the second line and a second device for cooling the first fluid circulating in the second line, the management system comprising a bifurcation between the second line and the cooling line installed upstream of the first cooling device.

According to an optional characteristic of the invention, the management system comprises at least one phase separator of the first fluid installed on the second line between the second compressor and an intersection between the pipe and the second line, the management system comprising a line of gas extending between the separator and the second line, the gas line being connected to the second line between the cooling device and the intersection between the pipe and the second line, the first fluid in the liquid state being suitable to flow from the separator to the intersection between the pipe and the second line through the second line, the first fluid in the gaseous state being capable of flowing from the separator to the second line through the gas line.

According to an optional characteristic of the invention, the management system comprises a first fluid phase separation device installed on the second line downstream of the cooling device, the management system comprising a return line which extends between the separation device and the first line and through which the first fluid in the gaseous state circulates.

According to an optional characteristic of the invention, the management system comprises a first pipe extending between the first line and the second line and a second pipe extending between the first line and the second line, the management system comprising a third compression member installed on the first line, the second compression member being installed between the first compression member and the third compression member, the first pipe emerging on the first line between the second compression member and the third compression member , the second pipe opening onto the first line between the first compression member and the second compression member, the management system comprising a first device for cooling the first fluid circulating in the second line and a second device for cooling the first fluid circulating in the second line, the cold generated by the first device cooling resulting from evaporation of the first fluid flowing in the first pipe and the cold generated by the second cooling device resulting from evaporation of the first fluid flowing in the second pipe, the first cooling device being installed upstream of the second cooling device on the second line. It is understood here that the first fluid circulating in the second line towards the first tank is cooled a first time at the level of the first cooling device, then a second time at the level of the second cooling device.

According to an optional characteristic of the invention, the cooling line is connected to the second line between the first cooling device and the second cooling device.

According to an optional feature of the invention, the cooling line is connected to the second pipe downstream of the second cooling device.

According to an alternative, the cooling line is connected to the second pipe upstream of the first cooling device.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description which follows on the one hand, and several examples of embodiment given by way of indication and not limitation with reference to the appended schematic drawings on the other. part, on which:

is a schematic representation of a first embodiment of a management system according to the invention;

is a schematic representation of a second embodiment of the management system according to the invention;

is a schematic representation of a third embodiment of the management system according to the invention;

is a schematic representation of a fourth embodiment of the management system according to the invention;

is a schematic representation of a fifth embodiment of the management system according to the invention.

The features, variants and different embodiments of the invention may be associated with each other, in various combinations, insofar as they are not incompatible or exclusive with respect to each other. In particular, variants of the invention may be imagined comprising only a selection of characteristics described below in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage and/or to differentiate the invention. compared to the prior art.

In addition, the terms "upstream" and "downstream" used in the remainder of the description refer to the direction of circulation of a first fluid and/or of a second fluid in a management system according to any embodiments which will be detailed below.

On the illustrated is a system 1 for managing the state of at least a first fluid 4 and a second fluid 8, a first tank 2 containing the first fluid 4 and a second tank 6 containing the second fluid 8. The first tank 2, the second tank 6 and/or the management system 1 can for example be installed on a ship transporting the first fluid 4 and the second fluid 8.

The first fluid 4 has a boiling temperature lower than the boiling temperature of the second fluid 8, these two temperatures being measured at identical pressure. The first fluid 4 is for example natural gas such as methane and has a boiling point of approximately -160° C., that is to say that the first fluid 4 is in liquid form when it has a temperature below -160°C at atmospheric pressure. The second fluid 8 is for example petroleum gas such as propane, butane or a mixture of propane and butane and has a boiling temperature of between 0° C. and -51° C. at atmospheric pressure. However, the first fluid 4 can also be petroleum gas such as propane, butane or a mixture of propane and butane, as long as the first fluid 4 has a lower boiling temperature than the second fluid 8.

According to the example illustrated here, the first fluid 4 and the second fluid 8 are petroleum gas, the first fluid 4 being for example a mixture composed of approximately 92% propane and approximately 8% butane and which has a boiling temperature of −47° C. at atmospheric pressure, while the second fluid 8 is for example composed of approximately 100% butane and has a boiling temperature of 0° C. at atmospheric pressure.

The first tank 2 and second tank 6 are designed to respectively store the first fluid 4 and the second fluid 8 in liquid form at a temperature lower than or equal to their boiling point at atmospheric pressure. For this, the tanks 2, 6 each consist at least of a sealed membrane in contact with one or the other of the fluids and of a thermally insulating barrier enveloping the sealed membrane and participating in maintaining one or the other. other fluids at a temperature below their boiling point. Advantageously, each of the tanks 2, 6 comprises a primary thickness composed of a primary sealing membrane in contact with one or other of the fluids, a thermally insulating primary barrier enveloping the primary sealing membrane, a secondary layer enveloping the primary layer and composed of a secondary sealing membrane in contact with the thermally insulating primary barrier and a thermally insulating secondary barrier surrounding the secondary sealing membrane.

According to an alternative of the invention, the second tank 6 comprises only the primary thickness, the thermally insulating primary barrier being in direct contact with the external environment of the second tank 6. It is understood that in this alternative, the second tank 6 does not include a secondary thickness, the thermal insulation being achieved solely by the primary barrier thermally insulating the primary thickness.

The first fluid 4 is stored in the first tank 2 mainly in liquid form, at atmospheric pressure. However, part of the first fluid 4 evaporates and forms a sky 10 of the first tank 2, in which the first fluid 4 is therefore present in gaseous form.

Similarly, the second fluid 8 is stored in the second tank 6 mainly in liquid form at atmospheric pressure. However, part of the second fluid 8 evaporates and forms a sky 11 of the second tank 6, in which the second fluid 8 is therefore present in gaseous form.

The management system 1 is configured on the one hand to reliquefy at least part of the first fluid 4 in gaseous form present in the top 10 of the first tank 2 and on the other hand to supply a consumption device with first fluid 4 , the latter using the first fluid 4 as fuel. For this, the management system 1 comprises on the one hand at least a first line 12 through which the first fluid 4 circulates from the first tank 2 to a plurality of compression members 14 and a second line 16 in which circulates the first fluid 4 in the liquid state and/or in the diphasic state from the first line 12 to the first tank 2 and on the other hand a pipe 45 extending between the second line 16 to the consumption device . Furthermore, the management system 1 comprises a cooling line 18 through which the first fluid 4 circulates from the second line 16 to the first line 12.

The management system 1 also comprises at least one line 20 for managing the state of the second fluid through which at least a portion of the second fluid 8 flows from the second tank 6 to a liquid outlet 22 of the second fluid 8 in the second tank 6. The liquid outlet 22 makes it possible in particular to project the cooled second fluid 8 into the second tank 6 to cool the second fluid 8 in particular present in the top 11 of the second tank 6. The lowering of the temperature of the second fluid 8 present in the top 11 of the second tank 6 makes it possible to reduce the pressure exerted by the second evaporated fluid 8 present in said top 11 of the second tank 6. According to an exemplary embodiment illustrated here on the , the liquid outlet 22 takes the form of a spray bar favoring the distribution in the sky 11 of the second fluid 8 projected.

According to the invention, the management system 1 comprises a unit 24 for cooling the second fluid 8 in the liquid state circulating in the management line 20, the cold generated by the cooling unit 24 being the result of evaporation of the first fluid 4 circulating in the cooling line 18. It is understood here that the first fluid 4 is at a sufficiently low temperature when it circulates through the cooling line 18 and the cooling unit 24 to cool the second fluid 8 circulating in the management line 20. In this case, the second fluid 8 transfers calories to the first fluid 4.

The first line 12 extends from the inside of the first tank 2, and more particularly comprises a gas inlet 26 at the level of the top 10 of the first tank 2 which opens onto the top 10 of the first tank 2 where is the gaseous phase of the first fluid 4. In this way, the first fluid 4 in the gaseous state present in the top 10 of the first tank 2 is directly in contact with the gas inlet 26 of the first line 12, the first fluid 4 in the gaseous state can thus be sucked up by the plurality of compression members 14.

The first fluid 4 in the gaseous state moves from the top 10 of the first tank 2 through the first line 12 towards the plurality of compression members 14 by a suction phenomenon generated by the plurality of compression members 14. More particularly, the plurality of compression members 14 is configured to increase the pressure of the first fluid 4 in the gaseous state before it is delivered to a consumer device.

As shown on the , the plurality of compression members 14 comprises a first compression member 14a, a second compression member 14b and a third compression member 14c arranged in this order on the first line 12, according to the direction of circulation of the first fluid 4 at the within said first line. The compression members 14 thus participate in delimiting a first portion 28 of the first line 12 extending between the gas inlet 26 and the first compression member 14a, a second portion 30 extending between the first compression 14a and the second compression member 14b, a third portion 32 extending between the first second compression member and the third compression member 14c and a fourth portion 34 extending between the third compression member 14c and the second line 16 .

The pressure of the first fluid 4 in the gaseous state increases as it circulates in the first line 12 through the plurality of compression members 14, the first fluid 4 being at atmospheric pressure at the level of the first portion 28 and passing at a pressure of approximately 24 bars at the level of the fourth portion 34.

As shown on the , a cooling liquid circulation system 36 comprises at least one heat exchange member 38 between the cooling liquid circulating in the circulation system 36 and the first fluid 4 in the gaseous state circulating in the first line 12. This heat exchange member 38 separates the first line 12 from the second line 16. More specifically, the heat exchange member 38 is arranged downstream of the fourth portion 34 of the first line 12.

The heat exchanger 38 exchanges calories between the cooling fluid and the first fluid 4. The cooling liquid can be a heat transfer fluid and/or water with glycol, the circulation system 36 being able to be for example, installed on the ship and directly connected to the body of water on which the ship is sailing.

Advantageously, the circulation system 36 comprises a first heat exchange member 40 installed at the level of the second portion 30 of the first line 12, a second heat exchange member 42 installed at the level of the third portion 32 of the first line 12 and a third heat exchange member 38 installed at the level of the fourth portion 34 of the first line 12, each of the heat exchange members 38, 40, 42 exchanging calories between the first fluid 4 at the gaseous state circulating in the first line 12 and the cooling fluid. It is understood that the alternation between the compression members 14 and the heat exchange members 38, 40, 42 arranged along the first line 12 makes it possible to lower the temperature of the first fluid 4 after each compression phase operated by a compression device.

In the example shown here on the , when the first fluid 4 passes through the plurality of compression members 14, the pressure and the temperature of the fluid are increased. In order to prevent this temperature from being too high, the first fluid 4 exchanges calories with the cooling fluid through the first, second and third heat exchange members 40, 42, 38. For example, a temperature of the first fluid 4 circulating in the second portion 30 downstream of the first heat exchange member 40 is approximately 7° C., a temperature of the first fluid 4 circulating in the third portion 32 downstream of the second heat exchange member heat 42 is approximately 40°C and a temperature of the first fluid 4 circulating in the fourth portion 34 downstream of the third heat exchange member 38 is greater than 43°C.

Moreover, the boiling temperature of a fluid also varies according to the pressure to which the fluid is subjected. The first fluid 4, which can for example be a mixture composed of approximately 92% propane and approximately 8% butane, has a boiling point of approximately 43° C. when it is subjected to a pressure of about 24 bar. It is understood from this that the first fluid 4 is in the gaseous state in the fourth portion 34 upstream of the third heat exchange member 38, passes to the liquid state or to the diphasic state by crossing the third heat exchange member. heat exchange 38 by heat exchange with the cooling fluid and circulates in the liquid state or in the diphasic state in the second line 16 downstream of the third heat exchange member 38. The first fluid 4 thus circulates in the liquid state or in the diphasic state downstream of the third heat exchange member 38 in the second line 16.

Furthermore, the term “two-phase state” is understood to mean a state in which part of the first fluid 4 is in the liquid state and another part of the first fluid 4 is in the gaseous state.

The first fluid 4 circulates in the second line 16 from the first line 12, and more particularly from the third heat exchange member 38, to the first tank 2.

As shown on the , the management system 1 comprises a phase separator 44 of the first fluid 4 disposed on the second line 16. The separator 44 is configured to separate the phases present in the first fluid 4 circulating in the second line 16. In other words , the separator 44 is configured so that the first fluid 4 in the liquid state is separated from the first fluid 4 in the gaseous state. The first fluid 4 in the liquid state separated in the separator 44 then circulates towards the second line 16 and/or towards the consumption device through the pipe 45. The management system 1 comprises a gas line 46 through which circulates the first fluid 4 in the gaseous state from the separator 44 to the second line 16.

As shown on the , the management system 1 comprises at least one pipe 48 which joins the first line 12 with the second line 16 and through which the first fluid 4 circulates from the second line 16 to the first line 12. The management system 1 comprises at least one device 50 for cooling the first fluid 4 circulating in the second line 16, the cold generated by the cooling device 50 resulting from evaporation of the first fluid 4 circulating in the pipe 48.

An intersection 52 is provided between the pipe 48 and the second line 16, at which the first fluid 4 can flow either towards the first tank 2 through the second line 16, or towards the first line 12 through the pipe 48, the cooling device 50 being configured so that an evaporation of the first fluid 4 circulating in the pipe 48 leads to a decrease in the temperature of the first fluid 4 circulating in the second line 16.

Furthermore and as illustrated in the , the gas line 46 is connected to the second line 16 downstream of the intersection 52 between the second line 16 and the pipe 48. The first fluid 4 in the gaseous state circulating in the gas line 46 mixing with the first fluid 4 in the liquid state flowing in the second line 16 downstream of the intersection 52, the first fluid 4 is in a two-phase state between the intersection 52 and the cooling device 50 in the second line 16.

More specifically, the cooling device 50 comprises at least one heat exchanger 54 and an expansion device 56, the heat exchanger 54 comprising a first passage 58 constituting the second line 16 and a second passage 60 constituting the pipe 48, the expansion device 56 being positioned on line 48 upstream of second passage 60. Heat exchanger 54 is configured to implement a heat exchange between first fluid 4 flowing in second line 16 and first fluid 4 flowing in conduct 48.

Configured in this way, the heat exchanger 54 exchanges calories between the first fluid 4 circulating in the second line 16 and the first fluid 4 circulating in the pipe 48, the exchange of calories between the first fluid 4 circulating in the second line 16 and the first fluid 4 circulating in the pipe 48 taking place in particular at the level of the first and second passages 58, 60 of the heat exchanger 54. The calories exchanged between the first fluid 4 circulating in the second line 16 and the first fluid 4 flowing in line 48 cause the temperature of the first fluid 4 flowing in the second line 16 to decrease, the first fluid 4 flowing in the second line 16 yielding calories to the benefit of the first fluid 4 flowing in the pipe 48.

This transfer of calories is obtained by the presence of the expansion device 56 which lowers the pressure of the first fluid 4 circulating in the pipe 48, favoring its change of state.

The temperature reduction between the first fluid 4 circulating upstream of the first passage 58 in the second line 16 and that of the first fluid 4 circulating downstream of the first passage 58 in the second line 16 is at least 20°C. Advantageously, this temperature difference is between 25°C and 35°C.

The decrease in the temperature of the first fluid 4 circulating in the second line 16 changes the first fluid 4 from a two-phase state to a liquid state. It is understood from this that the first fluid 4 circulating downstream of the first passage 58 of the heat exchanger 54 in the second line 16 is in the liquid state and has, for example, a temperature of approximately 14° C. and a pressure of about 24 bar.

As shown on the , the expansion device 56 of the cooling device 50 is installed upstream of the second passage 60 on the pipe 48. In other words, it is understood that the first fluid 4 in the liquid state which supplies the second passage 60 undergoes an expansion, that is to say a decrease in its pressure before joining the second passage 60, causing a change of state of the first fluid 4, thus passing from a two-phase state to a gaseous state within the second passage 60. By example, the first fluid 4 can be expanded to a pressure of approximately 3 bars, causing the first fluid 4 to pass from a pressure of approximately 24 bars upstream of the expansion device 56 to a pressure of 3 bars between the expansion device 56 and the first line 12.

The difference in pressure, and therefore in temperature, between the first fluid 4 in the gaseous state circulating in the second passage 60 and the first fluid 4 in the liquid or two-phase state circulating in the first passage 58 causes the cooling of the first fluid 4 in the liquid or diphasic state circulating in the first passage 58 and the evaporation of the first fluid 4 in the diphasic state entering the second passage 60.

As shown on the , the first fluid 4 in the gaseous and expanded state flowing downstream of the second passage 60 then joins towards the first line 12. Advantageously, the pipe 48 is connected to the first line 12 at the level of its second portion 30, and more precisely between the first heat exchange member 40 and the second compression member 14b. The first fluid 4 in the gaseous and expanded state is thus mixed with the first fluid 4 coming from the first heat exchange member 40, this mixture being sucked by the second compression member 14b towards the third portion 32 of the first line 12 .

As shown on the , the management system 1 comprises a device 62 for separating phases of the first fluid 4 installed on the second line 16 downstream of the cooling device 50, the management system 1 comprising a return line 64 extending between the separation 62 and the first line 12 and through which the first fluid 4 in the gaseous state circulates.

The separation device 62 comprises a separation body 66 and an expansion element 68 arranged on the second line 16 upstream of the separation body 66. The expansion element 68 makes it possible to bring the first fluid 4 circulating towards the body of separation 66 at a pressure substantially similar to the pressure of the first fluid 4 contained in the first tank 2, that is to say at atmospheric pressure.

More precisely, it is understood that the first fluid 4 in the liquid state which circulates in the second line 16 towards the first tank 2 undergoes an expansion, that is to say a reduction in its pressure before joining the first tank 2 , in order to align the pressure of the first fluid 4 with the pressure of the first fluid 4 contained in the first tank 2, This expansion of the first fluid 4 by the expansion member 68 causes a change of state of the first fluid 4, passing thus from a liquid state to a two-phase state where part of the first fluid 4 is in the liquid state and another part in the gaseous state. This decrease in pressure also causes a decrease in the temperature of the first fluid 4. For example, the first fluid 4 can be expanded substantially to a pressure of 1.2 bars, causing the first fluid 4 to pass from a pressure of approximately 24 bars upstream of the expansion element 68 at a pressure of approximately 1.2 bars downstream of the expansion element 68, the first fluid 4 having a temperature of approximately -50°C.

The first fluid 4 then circulates towards the separation body 66, the first fluid 4 possibly being in the liquid and/or diphasic state depending on the exact temperature at which it is. The separation body 66 is configured to separate the phases present in the first fluid 4 flowing from the expansion element 68 to the first tank 2. In other words, the separation body 66 is configured so that the first fluid 4 in the liquid state is separated from the first fluid 4 in the gaseous state. The first fluid 4 in the liquid state separated in the separation body 66 then circulates towards the first tank 2, while the first fluid 4 in the gaseous state joins the first portion 28 of the first line 12 through the line of return 64.

Advantageously, the second line 16 opens at the level of a fluid outlet 65 in the first tank 2, and in particular at the level of a bottom of the first tank 2, the first fluid 4 in the liquid state therefore flowing from the body separation 66 through the second line 16 towards the bottom of the first tank 2. According to an alternative, the second line 16 opens at the level of the top 10 of the first tank 2, the first fluid 4 in the liquid state being for example projected into the top 10 of the first tank 2, then cooling the first fluid 4 in the gaseous state present in the top 10 of the first tank 2.

On the example shown here on the , the management system 1 comprises an expansion unit 70 for the first fluid 4 arranged on the return line 64 and configured to cause the first fluid 4 to pass, for example, to the gaseous state flowing through the return line 64 from a pressure of 1.2 bar at atmospheric pressure.

The management system 1 also includes an evacuation line 72 connected to the return line 64 downstream of the expansion block 70 and leading to the external environment of the management system 1.

The management system 1 comprises a valve 74 for controlling the flow rate of the first fluid 4 in the gaseous state and disposed on the evacuation line 72, to control the flow rate of the first fluid 4 evacuated into the environment outside the management system. 1.

As shown on the , the cooling line 18 extends between the second line 16 and the first line 12. It is understood from this that the first fluid 4 circulates through the cooling line 18 from the second line 16 and towards the first line 12.

According to one characteristic of the invention, the cooling line 18 is connected to the pipe 48 downstream of the cooling device 50. The first fluid 4 flowing through the cooling line 18 from the second line 16 to the first line 12 passes through at least a part of the pipe 48 by mixing with the first fluid 4 circulating in the pipe 48 downstream of the cooling device 50. It is understood from this that the first fluid 4 coming from the cooling line 18 is mixed with the first fluid 4 circulating in the second portion 30 of the first line 12, by injection between the first heat exchange member 40 and the second compression member 14b.

According to the invention and as illustrated in the , the management system 1 comprises the line 20 for managing the state of the second fluid 8, in particular its pressure and/or its temperature, this management line 20 being intended to be traversed by the second fluid 8 sampled in the state liquid in the second tank 6. For this, the management line 20 comprises a liquid inlet 76 installed, for example, in a bottom of the second tank 6 in contact with the second fluid 8 in the liquid state contained in the second tank 6.

According to an exemplary embodiment of the invention, the management system 1 comprises at least one pumping device 78 disposed on the management line 20 upstream of the cooling unit 24. The pumping device 78 is configured to force the circulation of the second fluid 8 in the liquid state through the management line 20. For this, the pumping member 78 is installed at the level of the liquid inlet 76. In other words, the pump 78 is immersed in the second fluid 8 in the liquid state contained in the second tank 6. However, the pumping device 78 can be installed anywhere on the management line 20 as long as it puts the second fluid 8 in the liquid state within the management line 20.

The pumping member 78 increases the pressure of the second fluid 8 in the liquid state circulating in the management line 20. For example, the second fluid 8 in the liquid state circulating downstream of the pumping member 78 has a pressure of approximately 4 bars, the pumping member 78 thus causing the pressure of the second fluid 8 in the liquid state to pass from atmospheric pressure upstream of the pumping member 78 to a pressure of approximately 4 bars downstream of the pumping member 78.

As shown on the , the management line 20 comprises the liquid outlet 22 towards which the second fluid 8 in the liquid state flows through the management line 20. According to an exemplary embodiment, the liquid outlet 22 may comprise a spraying member suitable to project into the sky 11 of the second tank 6 the second fluid 8 in the liquid state from the management line 20.

According to the invention, the management system 1 comprises the unit 24 for cooling the second fluid 8 circulating in the management line 20, the cold generated by the cooling unit 24 resulting from evaporation of the first fluid 4 circulating in the cooling line 18. In this way, the management line 20 comprises a first part 80 upstream of the cooling unit 24 and a second part 82 downstream of the cooling unit 24. The second fluid 8 at the liquid state flowing through the second part 82 of the management line 20 thus has a temperature lower than the temperature of the second fluid 8 in the liquid state flowing in the first part 80 of the management line 20.

More particularly, and as illustrated in the , the cooling unit 24 comprises at least one heat exchanger 84 and an expansion member 86 installed on the cooling line 18 upstream of the heat exchanger 84, the heat exchanger 84 being configured to implement a heat exchange between the first fluid 4 circulating in the cooling line 18 and the second fluid 8 circulating in the management line 20. It is understood that the heat exchanger 84 is installed both on the cooling line 18 and on the management line 20 so that the first fluid 4 and the second fluid 8 pass through the heat exchanger 84.

For this, the heat exchanger 84 comprises at least a first pass 88 constituting the cooling line 18 and a second pass 90 constituting the management line 20, the expansion member 86 being arranged upstream of the first pass 88. The first fluid 4 circulating in the cooling line 18 crosses the heat exchanger 84 by passing through the first pass 88, the second fluid 8 circulating in the management line 20 crossing the heat exchanger 84 by passing through through the second pass 90. Configured in this way, the heat exchanger 84 exchanges calories between the first fluid 4 circulating in the cooling line 18 and the second fluid 8 circulating in the management line 20, the exchange of calories between the first fluid 4 circulating in the cooling line 18 and the second fluid 8 circulating in the management line 20 taking place in particular at the level of the first and second passes 88, 90 of the heat exchanger their 84. The calories exchanged between the first fluid 4 and the second fluid 8 cause the temperature of the second fluid 8 to decrease, the second fluid 8 transferring calories to the first fluid 4.

This heat transfer is also obtained by the presence of the expansion device 86 which lowers the pressure of the first fluid 4 circulating in the cooling line 18, favoring its change of state.

As shown on the , the expansion member 86 of the cooling unit 24 is installed upstream of the first pass 88 on the cooling line 18. In other words, it is understood that the first fluid 4 in the liquid state which supplies the first pass 88 undergoes relaxation, that is to say a reduction in its pressure before joining the first pass 88 where it evaporates. This expansion causes a change of state of the first fluid 4, the latter changing from a two-phase state to a gaseous state within the second pass 90. It is thus understood that the first fluid 4 can be expanded to a pressure of approximately 3 bars, causing the first fluid 4 to pass from a pressure of approximately 24 bars upstream of the expansion device 86 to a pressure of approximately 3 bars downstream of the expansion device 86.

The decrease in the pressure of the first fluid 4 through the expansion device 86 causes a change of state of the first fluid 4 and at the same time a decrease in its temperature. For example, the first fluid 4 has a temperature of approximately 14° C. upstream of the expansion device 86 and a temperature of approximately -30° C. between the expansion device 86 and the first pass 88 of the heat exchanger 84.

Advantageously, the temperature difference between the first fluid 4 circulating in the first pass 88 and the second fluid 8 in the liquid state circulating in the second pass 90 causes the cooling of the second fluid 8 in the liquid state circulating in the second pass. 90 and the evaporation of the first fluid 4 in the diphasic state entering the first pass 88. It is understood here that the second fluid 8 circulating in the second pass 90 yields calories to the benefit of the first fluid 4 circulating in the first pass 88 , the temperature of the first fluid 4 increasing as it passes through the first pass 88 and then sees its state pass from the diphasic state to the gaseous state.

For example, the temperature of the second fluid 8 in the liquid state is approximately 0° C. in a first part 80 of the management line 20, that is to say upstream of the second pass 90 of the heat exchanger 84, and about -10°C in a second part 82 of the management line 20, that is to say downstream of the second pass 90.

Furthermore, the first fluid 4 circulating in the cooling line 18 upstream of the expansion member 86 is in the liquid state, the first fluid 4 circulating in the cooling line 18 between the expansion member 86 and the The heat exchanger 84 is in the two-phase state and the first fluid 4 circulating in the cooling line 18 within the heat exchanger 84 and downstream of the latter is in the gaseous state. For example, the temperature of the first fluid 4 circulating in the cooling line 18 upstream of the expansion device 86 is approximately 14° C., the temperature of the first fluid 4 circulating in the cooling line 18 between the expansion device of expansion 86 and the heat exchanger 84 is approximately -30°C and the temperature of the first fluid 4 circulating downstream of the heat exchanger 84 is approximately -3°C.

According to the first embodiment illustrated in the , the first fluid 4 in the gaseous state circulating in the cooling line 18 downstream of the heat exchanger 84 is mixed with the first fluid 4 in the gaseous state circulating in the pipe 48 downstream of the cooling device 50, this mixture then being incorporated into the first fluid 4 in the gaseous state flowing in the second portion 30 of the first line 12 between the first heat exchange member 40 and the second compression member 14b.

Advantageously, the expansion device 86, the expansion device 56 and the first compression device 14a are configured to bring the first fluid 4 to the same pressure. It is understood from this that the first compression member 14a increases the pressure of the first fluid 4 circulating in the first line 12 up to a pressure of, for example, 3 bars. The expansion device 86 and the expansion device 56 reduce the pressure of the first fluid 4 circulating respectively in the cooling line 18 and the pipe 48 to a pressure similar to the pressure of the first fluid 4 circulating in the second portion 30 of the first line 12, that is to say for example at a pressure of 3 bars. The first fluid 4 in the gaseous state circulating in the pipe 48 downstream of the cooling device 50 is thus for example at a pressure of 3 bars, the first fluid 4 in the gaseous state circulating in the cooling line 18 downstream of the heat exchanger 84 also being at a pressure of 3 bars.

A second exemplary embodiment of the invention will now be described, in particular with reference to the . The elements which differentiate the second embodiment from the first embodiment will be described below, and reference will be made to the detailed description of the latter for the identical elements.

In this second exemplary embodiment, the pipe 48 is connected to the first line 12 at the level of the third portion 32, that is to say between the second heat exchange member 42 and the third compression member 14c. It is understood that the first fluid 4 in the gaseous state circulates in the pipe 48 downstream of the cooling device 50 towards the third portion 32 of the first line 12. The first fluid 4 in the gaseous state circulating in the pipe 48 in downstream of the cooling device 50 is mixed with the first fluid 4 in the gaseous state flowing in the third portion 32 of the first line 12 at a point located between the second heat exchange member 42 and the third compression member 14c.

The expansion device 56 is here configured to reduce the pressure of the first fluid 4 flowing in the pipe 48 to a pressure substantially similar to the pressure of the first fluid 4 in the gaseous state flowing in the third portion 32 of the first line 12 between the second heat exchange member 42 and the third compression member 14c. For example, the pressure of the first fluid 4 circulating downstream of the cooling device 50 is approximately 10.5 bars, the expansion device 56 causing the pressure of the first fluid 4 circulating in the pipe 48 to pass from a pressure of approximately 24 bars upstream of the expansion device 56 to a pressure of approximately 10.5 bars downstream of the expansion device 56.

As shown on the , the cooling line 18 extends for its part between the second line 16 and the second portion 30 of the first line 12. The cooling line 18 is directly connected to the first line 12 at the level of the second portion 30. The first fluid 4 in the gaseous state circulating in the cooling line 18 downstream of the cooling unit 24 is mixed with the first fluid 4 in the gaseous state circulating in the second portion 30 of the first line 12, at a point located between the first heat exchange member 40 and the second compression member 14b.

The expansion device 86 is here configured to reduce the pressure of the first fluid 4 circulating in the cooling line 18 to a pressure substantially similar to the pressure of the first fluid 4 in the gaseous state circulating in the second portion 30 of the first line 12. For example, the pressure of the first fluid 4 circulating in the cooling line 18 downstream of the cooling unit 24 is approximately 3 bars, the expansion member 86 passing the pressure of the first fluid 4 circulating in the cooling line 18 from a pressure of approximately 24 bars upstream of the expansion device 86 to a pressure of approximately 3 bars downstream of the expansion device 86.

A third exemplary embodiment of the invention will now be described, in particular with reference to the . The elements which differentiate the third embodiment from the first and second embodiments will be described below, and reference will be made to the detailed description of the latter for the identical elements.

As shown on the , the management system 1 comprises a first pipe 92 and a second pipe 94, each extending distinctly from one another between the second line 16 and the first line 12.

The first pipe 92 is connected on the one hand to the second line 16 and on the other hand to the third portion 32 of the first line 12, between the second heat exchange member 42 and the third compression member 14c. It is understood that the first fluid 4 circulating in the first conduit 92 mixes with the first fluid 4 circulating in the third portion 32 of the first line 12 at a point located between the second heat exchange member 42 and the third compression member 14c.

The management system 1 comprises a first cooling device 96 installed on the second line 16 and the first pipe 92, the first cooling device 96 comprising a first heat exchanger 98 and a first expansion device 100 arranged upstream of the first heat exchanger 98 on the first pipe 92. The first heat exchanger 98 is configured to perform an exchange of calories between the first fluid 4 flowing in the first pipe 92 and the first fluid 4 flowing in the second line 16. For this, the first heat exchanger 98 comprises a first conduit 102 constituting the second line 16 and a second conduit 104 constituting the first conduit 92. It is understood that the first fluid 4 circulating in the second line 16 passes through the first heat exchanger 98 at the level of the first conduit 102 and that the first fluid 4 circulating in the first conduit 92 passes through the first heat exchanger 98 at nor calf of the second conduit 104.

Furthermore, it is understood that a first intersection 521 between the first pipe 92 and the second line 16 is arranged between the separator 44 and the first cooling device 96. The first fluid 4 circulating at the level of the first intersection 521 can thus continue to circulate in the second line 16 towards the first cooling device 96 and/or in the first pipe 92 towards the first line 12.

The first expansion device 100 is here configured to reduce the pressure of the first fluid 4 in the liquid state flowing in the first conduit 92 to a pressure substantially similar to the pressure of the first fluid 4 in the gaseous state flowing in the third portion 32 of the first line 12. For example, the pressure of the first fluid 4 circulating downstream of the first cooling device 96 is approximately 10.5 bars, the first expansion device 100 passing the pressure of the first fluid 4 circulating in the first pipe 92 from a pressure of approximately 24 bars upstream of the first expansion device 100 to a pressure of approximately 10.5 bars downstream of the first expansion device 100.

The heat exchange between the first fluid 4 circulating in the second line 16 and the first fluid 4 circulating in the first conduit 92 takes place in particular at the level of the first heat exchanger 98, and more particularly at the level of the first conduit 102 and the second conduit 104. The first fluid 4 circulating in the first conduit 102 yields calories to the benefit of the expanded first fluid 4 circulating in the second conduit 104. In other words, the first fluid 4 circulating in the second conduit 104 cools the first fluid 4 flowing in the first conduit 102, the temperature of the first fluid 4 flowing in the first conduit 102 decreasing while the temperature of the first fluid 4 flowing in the second conduit 104 increases. The increase in the temperature of the first fluid 4 circulating in the second conduit 104 causes said first fluid 4 to pass from a two-phase state to a gaseous state.

As shown on the , the second pipe 94 is connected on the one hand to the second line 16 and on the other hand to the second portion 30 of the first line 12 between the first heat exchange member 40 and the second compression member 14b. It is understood that the first fluid 4 circulating in the second conduit 94 mixes with the first fluid 4 circulating in the second portion 30 of the first line 12 at a point located between the first heat exchange member 40 and the second compression member 14b.

Furthermore, the second pipe 94 is connected to the second line 16 downstream of the first cooling device 96. It is understood that a second intersection 522 between the second pipe 94 and the second line 16 is placed between the first cooling device 96 and the separation device 62. The first fluid 4 circulating in the second line 94 comes from the first fluid 4 cooled by the first cooling device 96 and circulating in the second line 16.

The management system 1 comprises a second cooling device 106 installed on the second line 16 and the second pipe 94, the second cooling device 106 comprising a second heat exchanger 108 and a second expansion device 110 arranged upstream of the second heat exchanger 108 on the second pipe 94. The second heat exchanger 108 is configured to perform an exchange of calories between the first fluid 4 flowing in the second pipe 94 and the first fluid 4 flowing in the second line 16, downstream of the first cooling device 102. For this, the first heat exchanger 98 comprises a first channel 112 constituting the second line 16 and a second channel 114 constituting the second pipe 94. It is understood that the first fluid 4 circulating in the second line 16 passes through the second exchanger thermal 108 through the first channel 112 and that the first fluid 4 circulating in the second conduit ite 94 crosses the second heat exchanger 108 by the second channel 114.

The second expansion device 110 is here configured to reduce the pressure of the first fluid 4 in the liquid state flowing in the second pipe 94 to a pressure substantially similar to the pressure of the first fluid 4 in the gaseous state flowing in the second portion 30 of the first line 12. For example, the pressure of the first fluid 4 circulating downstream of the second cooling device 106 is approximately 3 bars, the second expansion device 110 passing the pressure of the first fluid 4 circulating in the second pipe 94 from a pressure of approximately 24 bars upstream of the first expansion device 100 to a pressure of approximately 3 bars downstream of the second expansion device 110.

The expansion of the first fluid 4 circulating in the second conduit 94 from a pressure of approximately 24 bars to a pressure of approximately 3 bars causes a decrease in the temperature of the first fluid 4 circulating in the second channel 114. The first fluid 4 circulating between the second expansion device 110 and the second channel 114 is in the two-phase state, and it evaporates during its passage within the second channel 114.

The heat exchange between the first fluid 4 circulating in the second line 16 and the first fluid 4 circulating in the second conduit 94 takes place in particular at the level of the second heat exchanger 108, and more particularly at the level of the first channel 112 and the second channel 114. The first fluid 4 circulating in the first channel 112 transfers calories to the expanded first fluid 4 circulating in the second channel 114. In other words, the first fluid 4 circulating in the second channel 114 cools the first fluid 4 circulating in the first channel 112, the temperature of the first fluid 4 flowing in the first channel 112 decreasing while the temperature of the first fluid 4 flowing in the second channel 114 increases. The increase in the temperature of the first fluid 4 circulating in the second channel 114 changes said first fluid 4 from a two-phase state to a gaseous state.

According to the invention, a bifurcation 116 between the cooling line 18 and the second line 16 is positioned between the first cooling device 96 and the second cooling device 106. It is understood that the first fluid 4 circulating in the second line 16 in downstream of the first cooling device 96 can then flow either to the cooling unit 24 through the cooling line 18, or to the first line 12 through the second pipe 94, or to the first tank 2 through the second line 16. Advantageously, the bifurcation 116 between the cooling line 18 and the second line 16 is installed between the first cooling device 96 and the second intersection 522 between the second line 16 and the second pipe 94.

In this configuration, the cooling line 18 extends between the second line 16 and the second pipe 94, the cooling line 18 being connected to the second pipe 94 downstream of the second cooling device 106. It is understood here that the first fluid 4 in the gaseous state circulating in the cooling line 18 downstream of the cooling unit 24 mixes with the first fluid 4 in the gaseous state circulating in the second pipe 94 downstream of the second cooling device 106 before be incorporated into the first fluid 4 in the gaseous state flowing in the second portion 30 of the first line 12.

It is understood from the above that part of the first fluid 4 is driven in recirculation through the management system 1, this part of the first fluid 4 mainly participating in the cooling of the first fluid 4 and/or of the second fluid 8.

According to a fourth embodiment of the invention illustrated in the , the bifurcation 116 between the cooling line 18 and the second line 16 is installed between the second cooling device 106 and the separation device 62. It is understood here that the first fluid 4 in the liquid state flowing downstream of the second device 106 circulates either to the separation device 62 through the second line 16, or to the cooling unit 24 through the cooling line 18.

It is understood from the above that this configuration allows the first 4 to arrive at the level of the expansion device 86 at a lower temperature compared to the configurations described previously in the first, second and third embodiments. After passing through the expansion member 86, the first fluid 4 is expanded and has an even lower temperature, then optimizing the cooling of the second fluid 8 carried out in the heat exchanger 84. In other words, in the example illustrated here, the first fluid 4 circulating between the expansion member 86 and the heat exchanger 84 has a much lower temperature compared to the first fluid 4 circulating in the configurations described in the first, second and third embodiments , which makes it possible to more effectively reduce the temperature of the second fluid 8 at the level of the heat exchanger 84.

According to a fifth embodiment of the invention illustrated in the , the bifurcation 116 between the cooling line 18 and the second line 16 is installed between the separator 44 and the first cooling device 96. It is understood here that the first fluid 4 in the liquid state flowing downstream of the separation body 66 flows either to the first cooling device 96 through the second line 16 or through the first conduit 92, or to the cooling unit 24 through the cooling line 18. More particularly, the bifurcation 116 between the second line 16 and the cooling line 18 is installed at the level of the first intersection 521 between the second line 16 and the first conduit 92. However, a management system 1 where the bifurcation 116 between the second line 16 and the cooling line 18 would be installed between the separator 44 and the intersection 52 between the second line 16 and the first conduit 92 or between the intersection 52 between the second line 16 and the first con pick 92 and the first cooling device 96 would not depart from the scope of the invention.

The present invention cannot however be limited to the means and configurations described and illustrated here and it also extends to any equivalent means and configuration as well as to any technically effective combination of such means. In particular, all of the elements leading to a modification of the pressure, the temperature and/or the state of the first fluid 4 and/or of the second fluid 8 could be modified without harming the invention insofar as they fulfill the functionalities described in this document.

Claims (15)

System for managing (1) the state of a first fluid (4) contained in a first tank (2) and the state of a second fluid (8) contained in a second tank (6), the first fluid (4) having a boiling temperature lower than a boiling temperature of the second fluid (8) at identical pressure, the management system (1) comprising at least a first line (12) intended to be traversed by the first fluid (4) withdrawn in the gaseous state from the first tank (2) and which extends between a gas inlet (26) configured to open onto the first tank (2) to a heat exchange member (38, 40, 42) configured to condense the first fluid (4), the first line (12) comprising at least a first compression member (14a) and a second compression member (14b), the management system (1 ) comprising a second line (16) intended to be traversed by the first fluid (4) in the liquid state and/or in the diphasic state and which extends from the exchange member of heat (38, 40, 42) to a second orifice (65) configured to open onto the first tank (2), the management system (1) comprising at least one cooling line (18) which extends from the second line (16) to the first line (12) and intended to be traversed by the first fluid (4), the cooling line (18) being connected to the first line (12) between the first compression member (14a) and the second compression member (14b), the management system (1) comprising at least one line (20) for managing the state of the second fluid (8) intended to be traversed by the second fluid (8 ), characterized in that the management system (1) comprises at least one unit (24) for cooling the second fluid (8) circulating in the management line (20), the cold generated by the cooling unit (24 ) resulting from evaporation of the first fluid (4) circulating in the cooling line (18). Management system (1) according to Claim 1, in which the cooling unit (24) comprises at least one heat exchanger (84) and an expansion member (86) installed on the cooling line (18) between the second line (16) and the heat exchanger (84), the heat exchanger (84) being configured to implement a heat exchange between the first fluid (4) circulating in the cooling line (18) and the second fluid (8) circulating in the management line (20). Management system (1) according to Claim 2, in which the heat exchanger (84) comprises at least a first pass (88) constituting the cooling line (18) and a second pass (90) constituting the line management (20), the expansion member (86) being disposed between the second line (16) and the first pass (88). Management system (1) according to any one of the preceding claims, comprising at least one pumping member (78) arranged on the management line (20) upstream of the cooling unit (24). Management system (1) according to any one of the preceding claims, comprising at least one pipe (48) extending between the second line (16) and the first line (12), the pipe (48) being connected to the first line (12) between the first compression member (14a) and the second compression member (14b), the management system (1) comprising at least one device (50) for cooling the first fluid (4) circulating in the second line (16), the cold generated by the cooling device (50) resulting from evaporation of the first fluid (4) circulating in the pipe (48). Management system (1) according to claim 5, in which the cooling device (50) comprises at least one heat exchanger (54) and an expansion device (56), the heat exchanger (54) comprising a first passage ( 58) constituting the second line (16) and a second passage (60) constituting the pipe (48), the expansion device (56) being arranged on the pipe (48) between the second line (16) and the second passage (60), the heat exchanger (54) being configured to implement a heat exchange between the first fluid (4) circulating in the second line (16) and the first fluid (4) circulating in the conduit (48 ). Management system (1) according to any one of claims 5 or 6, comprising at least a first heat exchange member (38, 40, 42) between the first fluid (4) and a cooling fluid and a second heat exchange member (38, 40, 42) between the first fluid (4) and the cooling fluid, the first heat exchange member (38, 40, 42) being installed between the first compression member ( 14a) and the second compression member (14b), the pipe (48) being connected to the first line (12) between the first heat exchange member (40) and the second compression member (14b). Management system (1) according to any one of claims 5 to 7, in which the cooling line (18) is connected to the pipe (48) between the first line (12) and the cooling device (50). Management system (1) according to any one of claims 5 to 8, comprising a bifurcation (116) between the second line (16) and the cooling line (18) installed between the second orifice (65) arranged in the first tank (2) and the cooling device (50). Management system (1) according to any one of Claims 5 to 8, comprising a bifurcation (116) between the second line (16) and the cooling line (18) installed between the second compression member (14b) and the cooling device (50). Management system (1) according to any one of claims 5 to 10, comprising at least one phase separator (44) of the first fluid installed on the second line (16) between the second compressor (14b) and an intersection (52 ) between the pipe (48) and the second line (16), the management system (1) comprising a gas line (46) extending between the separator (44) and the second line (16), the gas (46) being connected to the second line (16) between the cooling device (50) and the intersection (52) between the pipe (48) and the second line (16), the first fluid (4) at the the liquid state being capable of flowing from the separator (44) towards the intersection (52) between the pipe (48) and the second line (16) through the second line (16), the first fluid (4) at the the gaseous state being capable of flowing from the separator (44) towards the second line (16) through the gas line (46). Management system (1) according to any one of claims 5 to 11, comprising a device (62) for separating the first fluid (4) installed on the second line (16) downstream of the cooling device (50), the management system (1) comprising a return line (64) which extends between the separation device (62) and the first line (12) and through which the first fluid (4) in the gaseous state circulates. Management system (1) according to any one of the preceding claims, comprising a first line (92) extending between the first line (12) and the second line (16) and a second line (94) extending between the first line (12) and the second line (16), the management system (1) comprising a third compression member (14c) installed on the first line (12), the second compression member (14b) being framed by the first compression member (14a) and the third compression member (14c), the first conduit (92) opening onto the first line (12) between the second compression member (14b) and the third compression member (14c) , the second pipe (94) opening onto the first line (12) between the first compression member (14a) and the second compression member (14b), the management system (1) comprising a first cooling device (96) of the first fluid (4) circulating in the second line (16) and a second e device (106) for cooling the first fluid (4) circulating in the second line (16), the cold generated by the first cooling device (96) resulting from evaporation of the first fluid (4) circulating in the first pipe (92) and the cold generated by the second cooling device (106) resulting from evaporation of the first fluid (4) circulating in the second pipe (94), the first cooling device (96) being installed upstream of the second cooling device (106) on the second line (16). A management system (1) according to claim 13, wherein the cooling line (18) is connected to the second line (16) between the first cooling device (96) and the second cooling device (106). Management system (1) according to any one of claims 13 or 14, in which the cooling line (18) is connected to the second pipe (94) downstream of the second cooling device (106).