Patent Application
20160327210
The present invention relates to a system for the reversible storage of hydrogen H2 in solid form, comprising a tank the vessel of which contains a heat exchanger which contains metal hydrides.
The present invention seeks to simplify the design and production of the integrated heat exchanger.
The possible applications of the invention are numerous and may relate to the entire field of hydrogen storage applications.
This may be H2 storage systems with tanks dedicated to means of transport, such as boats, submarines, motor cars, buses, trucks, site vehicles, two-wheeled vehicles and systems from the field of portable power supplies, such as batteries for mobile electronic devices (mobile telephones, laptop computers, etc.).
This may also be stationary systems for the storage of H2 in larger quantities, such as electric generator sets, the storage of H2 produced by intermittent energy (wind turbines, photovoltaic panels, geothermal, etc.).
In general, the system according to the invention may be used solely for the purposes of transporting hydrogen, but it may also be used for the on-board storage of hydrogen for a fuel cell or combustion engine or even for stationary hydrogen storage.
Because, notably, of the depletion of crude oil reserves, alternative energy sources are being sought. One of the promising vehicles carrying these energy sources is hydrogen which can be used in fuel cells to produce electricity.
Hydrogen is an element which is present very extensively throughout the universe and on earth; it can be produced from coal, natural gas or other hydrocarbons but may also be produced by simple electrolysis of water using, for example, electricity produced by solar or wind energy.
Fuel cells operating on hydrogen are already used in certain applications, for example in motor vehicles, but are still not very widely adopted notably because of the precautions that have to be taken and the difficulties associated in storing the hydrogen.
In order to reduce the storage volume, the hydrogen can be stored in the form of compressed gaseous hydrogen at between 350 and 700 bar, but this densification of the energy can be further improved by incorporating hydrides into the pressure vessel.
In order to be even denser yet, the hydrogen may also be stored in liquid form, although this storage provides only a low storage efficiency and does not allow for long-term storage. The transition of a volume of hydrogen from the liquid state to the gaseous state under normal pressure and temperature conditions produces an increase in volume by a factor of around 800. Tanks that store hydrogen in liquid form are generally not very able to withstand mechanical impact and that poses significant safety problems.
There is also the ability to store hydrogen in solid form using hydrides. This storage allows for a high volumetric storage density while at the same time minimizing the energy impact of storage on the overall efficiency of the hydrogen chain, i.e. from its production to its conversion into another energy.
The principle of solid storage of hydrogen in the form of hydrides is as follows: certain materials and, in particular, certain metals, have the ability to absorb hydrogen to form a hydride, this reaction is called absorption. The hydrides formed can once again revert to gaseous hydrogen and a metal. This reaction is called desorption. Absorption or desorption occur depending on the partial pressure of hydrogen and on the temperature.
Use is made, for example, of a metal powder that is brought into contact with hydrogen, an absorption phenomenon occurs and a metal hydride is formed. The release of the hydrogen occurs according to a desorption mechanism.
The storage of the hydrogen is an exothermal reaction, i.e. one which releases heat, whereas the release of the hydrogen is an endothermal reaction, i.e. a reaction that absorbs heat.
It is notably the object to have a rapid charging of the metal powder with hydrogen. In order to obtain such rapid charging, the heat produced during this charging needs to be removed in order to prevent it slowing the absorption of hydrogen onto the powder or the metal matrix. During the discharging of hydrogen, heat is applied. As a result, the effectiveness of the cooling and of the heating govern the charging and discharging rates.
In other words, it is necessary to remove heat during absorption and to supply heat during desorption in order to facilitate the reactions and increase the efficiency of the hydride in terms of the flow rate of hydrogen entering or leaving the storage tank. Thus, a tank of hydrogen in the form of metal hydrides generally comprises a vessel containing the hydrides and within it incorporates a heat exchanger.
The design and sizing of this integrated exchanger need to meet a number of key criteria that can be listed as follows:
Another problem arises when the difference in the pressure between that of the hydrogen gas in the tank and that of the heat-transfer fluid in the integrated exchanger is very different. In general, the heat-transfer fluid is at a pressure of a few bar, whereas the hydrogen may be at a far higher pressure, for example 350 bar.
The high hydrogen pressure is therefore applied to the outside of the pipes of the heat-transfer fluid circuit, which places extremely high mechanical stress on these pipes within the integrated exchanger.
The existing solution requires very substantial pipe wall thicknesses. For example a cylindrical tube subjected to a high external pressure is engineered against buckling, and its wall thicknesses are therefore very great, something which, on the one hand, makes the hydrogen storage tank heavier and more expensive and, on the other hand, is detrimental to a good transfer of heat between the hydride and the heat-transfer fluid, because the thermal resistance increases with the wall thickness of the heat-transfer fluid circulation pipes.
There is therefore a need to improve further the systems for the reversible storage of hydrogen with a tank containing metal hydrides and incorporating a heat exchanger within it notably with a view to improving the heat transfer between the metal hydride or hydrides and the hydrogen, and reducing the mass and production cost of the tank.
The object of the invention is to satisfy this requirement, at least in part.
In order to do this, one subject of the invention is a reversible hydrogen-storage system comprising:
A <<heat exchanger>> here and within the context of the invention means a device comprising at least one tube of any cross section through which a heat-transfer fluid circulates and which is arranged at least partially in a bed of metal hydride powder inside the vessel. Heat-conducting elements such as fins, filaments, a metal foam, etc. may be connected to a heat exchanger tube according to the invention.
A <<value close to>> here and within the context of the invention means a substantially equal pressure value in the first and second circuits, with a difference typically of 1 bar or even 2 to 3 bar, or even of the order of around ten bar.
It is emphasized that the first circuit provides direct contact between the hydrogen and the hydride material.
Thus, the invention essentially consists in reducing the difference in pressure between the two fluids, the hydrogen and the heat-transfer fluid, within the tank to small values.
Within the context of the invention, it is the pressure of the hydrogen that is the deciding factor notably because the hydrogen may be compressed to high pressures, typically to 350 bar or beyond, typically up to 1000 bar in order to be stored in stationary tanks. As a result, the invention consists in pressurizing the heat-transfer fluid so that it reaches at least the pressure of the hydrogen.
The fact of reducing this pressure difference makes it possible to conceive of lightening the structures of the heat exchangers integrated into the hydrogen tanks by using tubes with thinner walls. Having thinner walls offers two major advantages, namely first a reduction in weight and second a reduction in thermal resistance, because the entire heat flux passes across this tube wall. This is an undeniable advantage in the case of on-board tanks, and in general affords improvements in terms of gains of efficiency and savings on cost.
Another advantage is the ability to adopt heat exchanger tube shapes that are non-circular. It is thus possible advantageously to conceive of tubes of square, rectangular, triangular, oblong, cross-shaped cross section or even of four-arm or multi-arm star-shaped cross section. These latter star-shaped cross sections have the notable advantages of increasing the heat-exchange surface area and of being easier to integrate into the heat exchanger.
The heat-transfer fluid may be at a pressure close to that of the hydrogen.
Advantageously, for a tube of circular cross section, the pressure of the heat-transfer fluid is slightly higher than that of hydrogen. Thus, the pipes (tubes) of an exchanger integrated into the tank are in an internal-pressure mechanical-stress mode, namely are stressed from the inside of the pipes toward the outside within the tank vessel, rather than being in an external-pressure stress mode which presents problems of buckling. The internal-pressure stressing is far easier to master.
Thus, for preference, it is preferable for the heat-transfer fluid to be at a higher pressure than the H2 gas.
In other words, the sizing of the heat exchange is easier.
In other words still, by virtue of the invention, the design and creation of the exchanger integrated within the hydrogen tank is simplified, it being possible for this exchanger to be more compact, more lightweight and perform better than an exchanger according to the prior art.
For preference, the heat-transfer fluid is a liquid, preferably based on water, notably containing glycol or the like.
According to one advantageous embodiment, the pressurizing means may consist in the tube or tubes of the heat exchanger, the cross section of the tube or tubes of the exchanger being designed so as to deform enough to bring the pressure in the second circuit to a value close to that in the first circuit. In other words, it is possible according to this embodiment to conceive of the pressure-equalizing being performed by the deformation of the cross section of the tube of the exchanger itself, taking on the role of a flexible membrane. For example, a tube with a star-shaped cross section has the ability to deform easily, and thus to transmit pressure from the first circuit to the second circuit.
Alternatively or in combination, according to another advantageous embodiment, the pressurizing means consisting in a pressure equalizer consisting of a vessel inside which there is fixed a mobile element dividing a first chamber from a second chamber in a sealed manner, the first chamber being connected to the first circuit, the second chamber being connected to the second circuit.
The mobile element may be a flexible membrane or a piston. Rather than a membrane or piston accumulator, it is also possible to conceive of a compressor for pressurizing the heat-transfer fluid circuit. In that case, a feedback control circuit is additionally provided to ensure that the pressure supplied by the compressor mirrors that of the hydrogen.
According to a first alternative form, the pressurizing means is arranged outside the H2 storage tank.
According to a second alternative form, the pressurizing means is arranged inside the vessel of the H2 storage tank.
According to one advantageous embodiment, the second circuit comprises a first pump and another heat exchanger constituting a first secondary exchanger. With this embodiment, the secondary fluid of the secondary exchanger is advantageously a liquid, preferably water, or a gas, preferably air.
Another aspect of the invention relates to a method for operating a system described previously, comprising a permanent pressurization step for bringing the pressure in the second circuit to a value close to that in the first circuit.
The pressurizing step is preferably performed automatically.
Advantageously, the pressure in the second circuit is higher than that of the first circuit.
For preference, the pressure in the first circuit is at least equal to 350 bar, that in the second circuit being around 2 to 3 bar higher.
The invention also relates to an electrical power supply unit comprising a fuel cell and a system described previously, the first secondary heat exchanger being connected to the fuel cell in such a way that the heat given off by the fuel cell in operation allows the desorption of hydrogen in the tank.
The invention finally relates to a stationary installation for refilling a unit as claimed in claim 14 with hydrogen, the installation comprising a second pump and a second secondary heat exchanger, the second pump and the second secondary heat exchanger being intended to be connected to the second circuit while the tank is being refilled with H2.
Other features and advantages of the invention will become better apparent from reading the detailed description of some exemplary embodiments of the invention, given by way of illustrative nonlimiting example with reference to the following figures among which:
The system 1 first of all comprises a storage tank 2 comprising a vessel 20 containing metal hydrides, not depicted, and incorporating within it a heat exchanger 21 constituting a primary exchanger.
A hydrogen circulation circuit 3 is connected to the inside of the vessel 20 in order to supply or recover the hydrogen H2 that is respectively to be absorbed or desorbed by the metal hydrides. The part 30 of the circuit 3 inside the vessel 20 constitutes one of the circuits of the primary exchanger 21. The circuit 3 ensures direct contact between the hydrogen and the hydride.
A heat-transfer liquid circulation circuit 4 is connected to the exchanger 21, the part 40 of this circuit 4 in the exchanger constituting the other of the circuits of the exchanger 21. This circuit 4 therefore has the function of being a cooling loop referred to as the primary cooling loop that enters the inside of the vessel 20 and re-emerges therefrom. In order to exchange heat with a secondary fluid, preferably a liquid, there is, within this loop 4, a secondary heat exchanger 41. The circulation of liquid within the loop 4 is ensured by a pump 42.
According to the invention, the loop 4 is pressurized to a pressure close to the hydrogen supply pressure, i.e. the pressure prevailing in the circuit 3 and in the vessel 20 of the tank 2 by means of a pressure equalizing means 5 arranged outside the tank 2.
As illustrated in
By way of advantageous example, the system 1 shown in
With the membrane accumulator 5, the water circulating in the loop 4 may be at a higher pressure of the order of 2 to 3 bar higher.
Suitable cooling may be obtained with a water flow rate during the charging of H2, of the order of 1 liter/second, the water temperature varying between 10 and 75° C.
With the membrane accumulator 5 according to the invention, the pressure difference between the heat-transfer circuit 4 and the hydrogen in the heat exchanger 21 integrated into the tank 2 is thus smaller.
However, care should be taken to ensure that the secondary heat exchanger 41 is capable of generating a greater pressure difference because it exchanges with a weakly pressurized circuit, a water or air circuit for example. Now, this greater pressure difference to be planned for on the secondary exchanger 41 does not present any disadvantage because:
Under stationary conditions, high heat fluxes, i.e. high flow rates, are handled by an external heat exchanger 45, the technology of which may be as usual, such as a water/air exchanger for example. The flow rate of water through the circuit 4 is assured by a pump 44 in the charging station.
Thus, in the mode of charging of hydrogen in the station, the valve V1 is closed, the pump 42 is switched off, the pump 44 is in operation, the connections R1, R2, and R3 are connected, the connection R3 allowing hydrogen to be carried into the tank 2.
In discharge mode, i.e. when the on-board fuel cell 7 is in operation, the valve V1 is open, the pump 42 is in operation, the connections R1, R2 and R3 are disconnected and sealed off. The fuel cell 7 is in operation, the pump 60 of the secondary circuit 6 is also in operation. With such a system, the heat lost by the fuel cell 7 is used to cause the hydrogen to desorb from the hydride in the tank 2, via the secondary circuit 6.
Other alternative forms and improvements may be anticipated without thereby departing from the scope of the invention.
Thus, while in the systems 1 depicted in
The tubes 400 of the exchanger 40 within the vessel 2 may have different shapes, such as a circular cross section (
The invention is not restricted to the examples that have just been described; notably features of the illustrated examples can be combined with one another in alternative forms that have not been illustrated.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1450008 | Jan 2014 | FR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/IB2014/067272 | 12/23/2014 | WO | 00 |
