The present invention relates to the aerospace field, and in particular to the field of vehicles propelled by rocket engines.
In the description below, the terms “upstream” and “downstream” are defined relative to the normal flow direction of propellants in the feed circuits of a rocket engine.
One of the main concerns in this field is that of obtaining satisfactory cooling of on-board heat sources. Specifically, in order to ensure that they operate properly, certain heat-generating devices, e.g. such as fuel cells, and batteries or electronic circuits, may need to have their operating temperatures maintained within a relatively narrow temperature range. However, constraints specific to this field can make it very difficult to remove the heat generated by such devices. In particular in the vacuum of space, there are very few channels for removing heat.
The present invention seeks to remedy those drawbacks. In particular, the invention seeks to propose a feed circuit for feeding a rocket engine with at least a first liquid propellant, which circuit also serves to cool at least one heat source.
This object is achieved by the fact that the feed circuit includes at least one buffer tank for said first liquid propellant and a first heat exchanger incorporated in said buffer tank and connected to a cooling circuit for cooling the at least one heat source. Thus, in operation, the heat generated by the heat source can be removed via the cooling circuit and said first heat exchanger to the liquid propellant in the feed circuit of the rocket engine. Unlike regenerative cooling of a rocket engine thrust chamber wall, in which the thrust chamber is called directly by the propellant, this cooling thus takes place via the intermediary of a cooling circuit interposed between the heat source and the propellant flowing through the feed circuit, thereby potentially enabling the temperature of the heat source to be regulated more accurately by the potential for regulating the flow rate of cooling fluid in the cooling circuit. Incorporating the first heat exchanger in a buffer tank of the feed circuit makes it possible to increase the heat power that is absorbed, even when the feed circuit is off and said first propellant is not flowing.
The present description also relates to the assembly comprising said feed circuit and the heat source provided with a cooling circuit connected to said first heat exchanger of the feed circuit. The heat source may in particular be a fuel cell. By way of example, such a fuel cell may be fed with the same propellants as the rocket engine in order to generate electricity for on-board systems of a vehicle propelled by the rocket engine. Alternatively, other types of on-board heat source, e.g. such as batteries or electronic circuits, could nevertheless be cooled in the same manner.
The present invention also relates to a vehicle comprising a rocket engine with said feed circuit and an on-board heat generating device with a cooling circuit connected to said first heat exchanger of the feed circuit. This vehicle may, for example, be a stage of a space launcher, a satellite, or any other type of vehicle that is propelled by a liquid propellant rocket engine.
In a second aspect, said first liquid propellant may in particular be a cryogenic liquid, and in particular liquid hydrogen, thus providing cooling that is even more effective because of its low temperature.
In a third aspect, said feed circuit may include a pump upstream from said first heat exchanger, in order to make the first propellant flow. This pump may, for example, be an electric pump or a turbopump. Nevertheless, the feed circuit could alternatively be configured in such a manner as to make the first propellant flow by other means, e.g. such as by pressurizing a tank upstream.
The heated first propellant downstream from the first heat exchanger may be used not only for feeding the thrust chamber of the rocket engine or, possibly, a gas generator or the heat source itself (e.g. when the heat source is a fuel cell), but it may also be used in the gaseous state for maintaining the internal pressure in at least one tank of the first propellant while the tank is emptying through the feed circuit. To do this, the feed circuit may include a branch leading to a high portion of this tank for the first propellant. The propellant in the gaseous state can thus be reinjected into the tank in order to maintain the internal pressure therein while the tank is emptying.
In a fourth aspect, downstream from said first heat exchanger, said feed circuit may include a branch passing through a second heat exchanger. The second heat exchanger can thus allow a flow of the first propellant diverted through said branch to pass into the gaseous state, even when the heat power of said heat generating device, on its own, is insufficient for that purpose. This flow of gas can thus be used, by way of example, for maintaining the internal pressure of a tank supplying the feed circuit with the first propellant as it empties. The present description also relates to the assembly comprising the feed circuit and a tank for said first liquid propellant, the tank being connected to the feed circuit upstream from said first heat exchanger, and also to said branch downstream from said second heat exchanger.
In a fifth aspect, said second heat exchanger may be incorporated in a tank for a second liquid propellant so as to be capable of heating the first liquid propellant by transferring heat from the second liquid propellant. In particular when the second liquid propellant presents a boiling point that is significantly higher than the first liquid propellant (for example when the first liquid propellant is liquid hydrogen and the second liquid propellant is liquid oxygen), this makes it possible not only to ensure that the first propellant passes into the gaseous phase in the second heat exchanger, but also, simultaneously, to cool the second propellant. This cooling of the second propellant makes it possible to avoid cavitation in a pump downstream from the second tank. The present description thus also relates to an assembly of this feed circuit and a tank for a second liquid propellant, and containing said second heat exchanger.
Finally, the present description also relates to a method of cooling a heat source, in which a cooling circuit of said heat source transfers the heat generated by the heat source to a first liquid propellant of a rocket engine via a first heat exchanger of a feed circuit for feeding said rocket engine at least with said first liquid propellant. As specified above, this first heat exchanger is contained in a buffer tank of the feed circuit for feeding the first propellant, and the heat source may be a fuel cell. Also, after this heat has been absorbed in the first heat exchanger, a portion of the flow of the first liquid propellant can then be diverted through a second heat exchanger in which it absorbs heat from a second propellant so as to reach the gaseous state prior to being injected into a tank for the first propellant feeding the feed circuit.
The invention can be well understood and its advantages appear better on reading the following detailed description of embodiments given as nonlimiting examples. The description refers to the accompanying drawings, in which:
In addition, for providing electrical power to on-board equipment, the vehicle 1 also has an on-board fuel cell 16 adapted to generate electricity as a result of a chemical reaction between the two propellants, which fuel cell is connected to feed circuits 12, 13 in order to be fed with these two propellants. Each of these circuits 12, 13 includes a micro-pump 14, 15 for controlling the flow rate of fuel supplied to the fuel cell 16. Nevertheless, because of the internal pressure in the tanks 3, 4, the micro-pumps 14, 15 could possibly be replaced by variable flow rate valves, with the internal pressure of the tanks 3, 4 then sufficing to cause the propellants to flow towards the fuel cell 16.
The fuel cell 16 is also provided with a cooling circuit 17 containing a cooling fluid such as, for example, helium and connected to a heat exchanger 18 incorporated in a buffer tank 20 of the feed circuit 6 for the first propellant. In the vehicle 1 shown, the flow of this cooling circuit in the cooling circuit 17 may be driven by, and may be regulated by means of a variable flow rate forced flow device 19, which device is in the form of a fan in the embodiment shown. Nevertheless, other alternatives could be envisaged both for driving the flow of cooling fluid and for regulating it. Thus, the cooling fluid could be driven by a thermosiphon, and its flow rate could be regulated by at least one variable flow rate valve.
In operation, after the valves 10 and 11 have been opened, the pumps 8, 9 drive the propellants via the feed circuits 6, 7 to feed the thrust chamber 5. The heat generated by the fuel cell 16, which is fed simultaneously with propellants via the feed circuits 12, 13 in order to generate electricity, is removed via the cooling circuit 17 and the heat exchanger 18 to the first propellant flowing through the feed circuit 6. In particular, in the embodiment described, the very low temperature of this first propellant, when it is a cryogenic liquid, enables this heat to be removed extremely effectively.
Because of the buffer tank 20, it is possible to remove a greater quantity of heat given off by the fuel cell 16 to the first propellant, with this continuing to apply even when the valves 10, 11 are closed and the pumps 8, 9 are off. A volume Vt of 30 liters (L) of liquid hydrogen in the buffer tank 20 can thus absorb the quantity of heat that corresponds to thermal power Pc of 100 watts (W) for one hour with a temperature rise AT of only 17 kelvins (K) in the liquid hydrogen.
A vehicle 1 in a second embodiment is shown in
In operation, after being heated by the heat exchanger 18, a portion of the flow of the first propellant leaving the first tank 3 through the first feed circuit 6 is diverted through the branch 21 to the second heat exchanger 23, in which it absorbs additional heat power from the higher-temperature second propellant, thereby passing into the gaseous state, prior to being injected into the top of the first tank 3 so as to maintain its internal pressure while it is emptying. If the first propellant is liquid hydrogen and the second propellant is liquid oxygen, the temperature difference between their respective boiling points at atmospheric temperature is nearly 70 K, thus enabling a more than adequate quantity of heat to be transferred for vaporizing the liquid hydrogen before their temperatures become equal, with this applying even when the liquid hydrogen is flowing at a high rate relative to the volume of liquid oxygen contained in the second tank. Simultaneously, this absorption of heat by the second propellant in the second heat exchanger 23 cools the second propellant, thereby enabling the saturation pressure of the second propellant being fed to the pump 9 to be reduced so as to reduce cavitation phenomena in the pump. This also makes it possible to allow the pressure and the temperature of the second propellant to fluctuate more widely in the second tank 4.
At the same time, in order to maintain the pressure in the second tank 4, a portion of the flow of the second propellant extracted from the second tank 4 via the second circuit 7 is diverted through the branch 40 and is heated in the heat exchanger 41 the by heat radiation from the thrust chamber 5, or by heat conduction, so that it passes into the gaseous phase prior to being reinjected into the second tank 4, in order to maintain the internal pressure therein. This diversion of flow is controlled by the valve 42.
Nevertheless, as an alternative to the pumps 8 and 9 in the first two embodiments, the flow of the propellants to the thrust chamber can also be provided by other means, for example such as pressurizing the tanks. Thus, in a third embodiment as shown in
Furthermore, as in the second embodiment, the first feed circuit 6 includes a buffer tank 20, and downstream therefrom it has a return branch 21 returning to the top of the first tank 3 via a variable flow rate valve 22 and a second heat exchanger 23 that is incorporated in the base of the second tank 4 in the proximity of its connection to the second feed circuit 7, thereby making it possible to reduce the consumption of pressurized gas from the tank 24 for the purpose of pressurizing the first propellant tank 3. Finally, in order to enable the propellant that has been diverted via the branch 21 to be reinjected in the gaseous phase into the top of the first tank 3, this branch 21 includes a forced flow device 30, more specifically in the form of a fan or a pump. The other elements of this vehicle 1 are essentially equivalent to elements of the second embodiment, and they are given the same reference numbers.
Although the present invention is described above with reference to specific embodiments, it is clear that various modifications and changes can be made to these embodiments without going beyond the general ambit of the invention as defined by the claims. Also, individual characteristics of the various embodiments described may be combined in additional embodiments. Thus, and by way of example, in a variant of the third embodiment, the vehicle could also have a branch for injecting the second propellants in the gaseous phase into the second tank, as in the second embodiment, including a device for forced flow of the second propellants in the gaseous phase. Consequently, the description and the drawings should be considered in a sense that is illustrative rather than restrictive.
Number | Date | Country | Kind |
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1350239 | Jan 2013 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2014/050045 | 1/10/2014 | WO | 00 |