FR3123643A1 - Installation and method for storing and distributing fluid - Google Patents

Abstract

Fluid storage and distribution installation comprising a reservoir (10) intended to store a cryogenic fluid, a withdrawal circuit comprising a withdrawal pipe (9) having a first end connected to a lower portion of the reservoir (10) and a second end intended to be connected to a member, said pipe (9) for withdrawing liquid comprising a set (8) of valve(s), the withdrawal circuit comprising a pipe (7) for withdrawing gas having a first end connected to an upper portion of the tank (10) and a second end intended to be connected to a member, the said gas withdrawal pipe (7) comprising a set (8) of valve(s), the installation (1) comprising a device regulating the pressure in the reservoir (10) comprising a buffer storage (4) connected to a lower portion of the reservoir (1) via a liquid transfer line (2) fitted with a set of flow control (3), the stored buffer (4) also being connected to an upper portion of the tank (1) via a gas transfer pipe (6) fitted with a set of flow control member(s) (5), the installation comprising an electronic control device (11) comprising a microprocessor and configured to control the set of flow control device(s) (3, 5) and control the pressure in the tank (2) by transferring a determined quantity of liquid from the tank (10) to the buffer storage (4) via the liquid transfer line (2) then by returning this quantity of fluid to the tank (10) via the gas transfer line (6). Figure of the abstract: Fig. 1

Description

Installation and method for storing and distributing fluid

The invention relates to a fluid storage and distribution installation as well as a method using such an installation.

The invention relates more particularly to an installation for storing and distributing fluid, in particular hydrogen, comprising a cryogenic tank intended to store a cryogenic fluid with a liquid phase and a gaseous phase, a withdrawal circuit comprising a pipe for withdrawing liquid having a first end connected to a lower portion of the reservoir and a second end intended to be connected to a user organ, the said liquid withdrawal pipe comprising a set of valve(s), the withdrawal circuit comprising a pipe for withdrawing gas having a first end connected to an upper portion of the reservoir and a second end intended to be connected to a user member, said gas withdrawal pipe comprising a set of valve(s), the installation comprising a device for regulating the pressure in the reservoir comprising a buffer storage connected to a lower portion of the reservoir via a liquid transfer line provided with a set of flow control member(s), the buffer storage also being connected to an upper portion of the reservoir via a gas transfer line provided with a set of member(s) ) (5) flow control.

Such installations can be fixed or mobile and in particular can be embedded in a fixed or interchangeable manner in vehicles to supply a fuel cell or an internal combustion engine for example.

See for example US5421160.

Currently, car, rail, maritime and air transport manufacturers are considering the storage of hydrogen in liquid form because of its energy density stored at low pressure. However, the gain in energy density of the hydrogen molecule can be reduced by the whole system to be implemented to store a cryogenic liquid as well as by the losses caused by natural thermal inputs.

The storage of hydrogen in cryogenic form induces specific thermal issues of which stratification is an integral part. Stratification corresponds to the establishment of a temperature gradient in the fluid contained in the reservoir between the liquid in the lower part and the gas in the upper part. The notable consequence is an increase in the rate of pressure rise, by a factor of 2 to 5 for example. Thus, a problem is to eliminate or limit the effects of stratification by remaining as close as possible to thermodynamic equilibrium in the reservoir (gas temperature = liquid temperature = saturation temperature).

The document CN2110337744 provides for a de-stratification thanks to the recirculation of the liquid present at the bottom of the tank towards the gaseous sky to recondense it using a rotating stirring shaft, a condenser with circulation pumps.

According to other known solutions, stratification is reduced by the use of passive anti-stratification devices in the tank (deflector or vertical walls), or by an active internal breaststroke system.

An object of the present invention is to overcome all or part of the drawbacks of the prior art noted above.

To this end, the installation according to the invention, moreover conforming to the generic definition given in the preamble above, is essentially characterized in that it comprises an electronic control unit comprising a microprocessor and configured to control the set of flow control member(s) and control the pressure in the reservoir by transferring a determined quantity of liquid from the reservoir to the buffer storage via the liquid transfer line and then returning this quantity of fluid into the tank via the gas transfer line.

Further, embodiments of the invention may include one or more of the following features:

• the flow control member(s) comprise(s) at least one of: a set of valve(s), check valve(s), check valve(s), discharge valve(s), or valve(s),
• the buffer storage has a volume of between 0.5% and 5% and in particular one hundredth of the volume of the tank,
• the liquid transfer line and the gas transfer line have no active fluid pump or circulators so that the transfer of fluid between the reservoir and the buffer storage is carried out passively by gravitation and/or pressure balancing.

The invention also relates to a method for storing cryogenic fluid comprising an installation conforming to any one of the characteristics above or below, in which the tank contains a liquefied gas, for example hydrogen, the method comprising a step of transferring a determined quantity of liquid from the reservoir to the buffer storage via the liquid transfer pipe, then a step of fluidic isolation of the buffer storage and of the reservoir during which the pressure in the storage is increased, then a step returning said determined quantity of pressurized fluid to the reservoir via the gas transfer line.

According to other features,

• the step of transferring a determined quantity of liquid from the reservoir to the buffer storage is carried out by gravitation and/or pressure balancing,
• the pressure increase in the buffer storage during the fluidic isolation step is achieved by spontaneous thermal inputs into said buffer storage,
• the step of returning the determined quantity to the tank is carried out by pressure balancing,
• the step of transferring a determined quantity of liquid from the reservoir to the buffer storage and/or the step of returning said determined quantity of pressurized fluid to the reservoir via the gas transfer line is carried out when the pressure in the reservoir exceeds a determined pressure threshold.

The invention may also relate to any alternative device or method comprising any combination of the features above or below within the scope of the claims.

Other features and advantages will appear on reading the description below, made with reference to the figures in which:

represents a side, schematic and partial view illustrating an example of structure and operation of installation according to the invention,

represents an example of evolution over time of pressures P and mass M within the reservoir and the buffer storage according to an example of use.

The illustrated fluid storage and distribution installation 1 comprises a cryogenic tank 10 intended to store a cryogenic fluid, in particular hydrogen, with a liquid phase and a gaseous phase. This installation 1 comprises a withdrawal circuit comprising a pipe 9 for withdrawing liquid having a first end connected to a lower portion of the reservoir 10 and a second end intended to be connected to a user member.

Said pipe 9 for withdrawing liquid comprising a set 8 of valve(s) or any other flow control member.

The withdrawal circuit further comprises a pipe 7 for withdrawing gas having a first end connected to an upper portion of the reservoir 10 and a second end intended to be connected to a user member.

The pipe 7 for withdrawing gas also comprises a set 8 of valve(s) or any other flow control member.

For the sake of simplification, the sets 8 of valve(s) of the withdrawal pipes 7, 9 have been symbolized by the same block 8 (or valve box). However, said sets of valves may use common valve(s) and pipes for the gas and the liquid and/or separate valves and pipes, such as at least one isolation valve, at least one flow control valve or depression. The withdrawal pipes 7, 9 can be connected to a plurality of user devices 12, 13 supplied with fluid drawn from the reservoir 10.

The installation 1 further comprises a device for regulating the pressure in the reservoir 10 making it possible, for example, to lower the pressure within it if necessary.

This device comprises a buffer storage 4 connected to a lower portion of the tank 1 via a liquid transfer pipe 2 fitted with a set of flow control member(s) 3 (for example at least one isolation valve which can be controlled and/or at least one of: a valve, a non-return valve, a discharge valve, a valve, or other).

The buffer storage 4 is also connected to an upper portion of the tank 1 via a gas transfer pipe 6 fitted with a set of flow control member(s) 5. Here also the example illustrated comprises a valve(s) 5 (for example minus an isolation valve which can be piloted) but could comprise at least one of: a non-return valve, a relief valve, a valve, or the like.

It should be noted that the pipe 6 for transferring gas may have at least one common portion with the pipe 7 for withdrawing gas. Similarly, the pipe 2 for transferring liquid may have at least one common portion with the pipe 9 for withdrawing liquid.

The installation 1 preferably comprises an electronic control unit 11 (electronic controller for example) comprising a microprocessor or a computer for example. This member 11 can be configured to control at least part of the sets of valve(s) 3, 5 and control the pressure in the tank 2, in particular by transferring a determined quantity of liquid from the tank 10 to the buffer storage 4 via pipe 2 for liquid transfer and then returning this quantity of fluid (preferably heated) to tank 10 via pipe 6 for gas transfer.

The buffer storage 4 has a volume preferably between 0.5% and 5% and in particular one hundredth of the volume of the reservoir 10. For example, the buffer storage 4 has a volume of the order of 0.1 liter to 100 liters (depending on tank size 10).

The liquid transfer pipe 2 and the gas transfer pipe 6 can advantageously be devoid of an active fluid pump or circulators so that the transfer of fluid between the reservoir 10 and the buffer storage 4 can be achieved passively by gravity. and/or pressure balancing, for example.

Thus, the buffer storage 4 of reduced volume can be connected in parallel with the reservoir 10. This buffer storage 4 can be filled with cryogenic fluid from the reservoir 10 to allow pressurization of the fluid in this buffer storage 4 after entry/exit closure via the closing of valves 3, 5 for example upstream and downstream of storage 4.

The pressurization of the fluid in the buffer storage 4 can be ensured via the natural thermal inputs (passive spontaneous heating for example) leading to the heating of the fluid.

The buffer storage 4 (just like the tank 10) is preferably thermally insulated, for example under vacuum and/or with insulation of the multilayer type or any other suitable cryogenic insulation.

For example, the buffer storage 4 is filled by the liquid transfer line 2 via at least one valve 3 (and/or a flow control device).

The buffer storage 4 can be emptied by the gas transfer line 6 (or discharge line 6) via at least one valve 5 (or any closing/opening and/or flow control member 5). This allows a return of the fluid from the buffer storage 4 to the inside of the tank 1, in particular in the gaseous sky of the latter. For example, the gas transfer line 6 may include one or more outlets or nozzles which extend into the tank 10.

A non-limiting example of operation will now be described with reference to the .

The curve provided with circles represents the evolution over time t (for example in hours) of the pressure P10 in the tank 10 (for example in bar). The curve provided with dashes represents the evolution over time t (for example in hours) of the pressure P4 in the buffer storage 4 (for example in bar). The discontinuous curve represents the evolution over time t (for example in hours) of the pressure P10E in the tank 10 at equilibrium (for example in bar). The curve provided with triangles represents the evolution over time t (for example in hours) of the mass m4 in the buffer storage 4.

During the temperature stratification of the fluid in reservoir 10 over time, the top of reservoir 10 (gas overhead and wall) will rise in temperature (gas temperature>saturation temperature>liquid temperature) and the pressure increases significantly more faster than at its steady state (typically two to five times faster).

To solve this problem, part of the cold liquid located at the bottom of the tank 10 can be withdrawn from the buffer storage 4 and then reinjected into the hot gaseous headspace to lower the pressure of the latter and approach the state of thermodynamic equilibrium of the mixing (cooling and condensation of superheated steam).

Thus, in a possible sequence it can occur successively:

• a rise in pressure P10 of storage 1 (due for example to natural thermal inputs), cf. ascending line illustrated,
• a liquid withdrawal from tank 10 of a volume corresponding to the volume of buffer storage 4 via for example the opening of valves (“communicating vessels” for example), cf. the increase in mass m4 in the buffer storage,
• fluidic isolation (closure) of buffer storage 4, cf. mass m4 which remains constant,
• a rise in isochoric pressure P4 in the buffer storage 4 (for example by natural thermal inputs, rise in rapid hydrostatic pressure),
• an opening of the valve 5 or other to reinject the compressed fluid into the storage 4 towards the gas headspace of the reservoir 10, cf. the decrease in mass m4,
• a decrease in pressure P10 in tank 10 until the pressures stabilize with storage 4 or the equilibrium pressure is reached in the mixture in tank 10.

Then the valve 5 connecting the buffer storage 4 to the upper end of the tank 10 can remain open and the valve 5 connecting the buffer storage 4 to the lower end of the tank 10 can remain closed in a standby mode. The process described above can be repeated if necessary.

The installation and the process make it possible to increase the thermal autonomy of a cryogenic tank (typically by a factor of two to five). The invention also allows a reduction in the size and mass of a tank with the same thermal autonomy compared to the prior art. The temperature of the fluid in the reservoir 10 is better controlled.

Claims (9)

Installation for storing and distributing fluid, in particular hydrogen, comprising a cryogenic tank (10) intended to store a cryogenic fluid with a liquid phase and a gaseous phase, a withdrawal circuit comprising a pipe (9) for withdrawing liquid having a first end connected to a lower portion of the reservoir (10) and a second end intended to be connected to a user member, said pipe (9) for withdrawing liquid comprising a set (8) of valve(s), the circuit withdrawal comprising a pipe (7) for withdrawing gas having a first end connected to an upper portion of the reservoir (10) and a second end intended to be connected to a user member, said pipe (7) for withdrawing gas comprising a assembly (8) of valve(s), the installation (1) comprising a device for regulating the pressure in the reservoir (10) comprising a buffer storage (4) connected to a lower portion of the reservoir (1) via a liquid transfer line (2) provided with a set of flow control member(s) (3), the buffer storage (4) also being connected to an upper portion of the tank (1) via a line (6) for gas transfer provided with a set of member(s) (5) for flow regulation, the installation being characterized in that it comprises an electronic control member (11) comprising a microprocessor and configured to control the set of flow control member(s) (3, 5) and control the pressure in the tank (2) by transferring a determined quantity of liquid from the tank (10) to the buffer storage (4) via the liquid transfer pipe (2) then returning this quantity of fluid to the tank (10) via the gas transfer pipe (6). Installation according to Claim 1, characterized in that the flow control member(s) comprise at least one of: a set of valve(s), check valve(s), non-return valve(s), discharge valve(s) , or valve(s). Installation according to Claim 1 or 2, characterized in that the buffer storage (4) has a volume of between 0.5% and 5% and in particular one hundredth of the volume of the tank (10). Installation according to any one of Claims 1 to 3, characterized in that the liquid transfer line (2) and the gas transfer line (6) have no pump or active fluid circulators so that the transfer of fluid between the reservoir (10) and the buffer storage (4) is produced passively by gravitation and/or pressure equalization. Process for storing cryogenic fluid comprising an installation (1) in accordance with any one of Claims 1 to 4, in which the tank (10) contains a liquefied gas, for example hydrogen, the process comprising a step of transferring of a determined quantity of liquid from the reservoir (10) to the buffer storage (4) via the liquid transfer pipe (2) then a step of fluidic isolation of the buffer storage (4) and of the reservoir (10) during which the pressure in the storage is increased, then a step of returning said determined quantity of pressurized fluid to the tank (10) via the gas transfer pipe (6). Method according to Claim 5, characterized in that the step of transferring a determined quantity of liquid from the reservoir to the buffer storage (4) is carried out by gravitation and/or pressure equalization. Method according to any one of Claims 5 or 6, characterized in that the increase in pressure in the buffer storage (4) during the fluid isolation step is achieved by spontaneous thermal inputs into the said buffer storage (4). . Method according to any one of Claims 5 to 7, characterized in that the step of returning the determined quantity to the tank (10) is carried out by pressure equalization. Method according to any one of Claims 5 to 8, characterized in that the step of transferring a determined quantity of liquid from the reservoir (10) to the buffer storage (4) and/or the step of returning the said determined quantity of pressurized fluid in the reservoir (10) via the gas transfer line (6) is produced when the pressure in the reservoir (10) exceeds a determined pressure threshold.