powertrain system for a motor vehicle comprising a fuel cell and an internal combustion engine
The powertrain system addresses reliability issues by using internal combustion engine exhaust water to humidify the fuel cell, ensuring efficient operation and preventing damage through controlled humidification.
Patent Information
- Authority / Receiving Office
- FR · FR
- Patent Type
- Applications
- Current Assignee / Owner
- AMPERE SAS
- Filing Date
- 2024-12-04
- Publication Date
- 2026-06-05
AI Technical Summary
Existing powertrain systems with both a fuel cell and an internal combustion engine consuming hydrogen suffer from insufficient reliability and performance, particularly due to damage from high power usage without adequate humidification of the fuel cell membrane.
A powertrain system with a first humidifier using water from the internal combustion engine's exhaust to humidify oxygen-rich air for the fuel cell, and a second humidifier using water from the fuel cell's reaction to further humidify the air, along with control mechanisms to manage water distribution and engine operation for optimal humidification.
Ensures the fuel cell operates efficiently at high power by maintaining membrane moisture, preventing damage and enhancing system reliability and performance.
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Abstract
Description
Title of the invention: Powertrain system for a motor vehicle comprising a fuel cell and an internal combustion engine Technical field of the invention
[0001] The invention relates to a powertrain system for a motor vehicle, the powertrain operating on hydrogen. More specifically, the invention relates to a powertrain system comprising a fuel cell and an internal combustion engine, the fuel cell and the internal combustion engine being designed to consume hydrogen. The invention further relates to a motor vehicle comprising such a powertrain system. The invention also relates to a method for controlling such a powertrain system. Prior art
[0002] Motor vehicles equipped with a powertrain system comprising a hydrogen tank, a fuel cell, an electrochemical battery, and an electric motor coupled to the vehicle's drive wheels are known. The fuel cell is capable of producing an electric current through a redox reaction between hydrogen from the tank and oxygen from the ambient air. The electric current produced by the fuel cell is used to charge the electrochemical battery. The electrochemical battery can then supply the electric motor with electric current to produce mechanical torque that drives the drive wheels. The advantages of such a solution are very high efficiency at low power and the absence of polluting emissions.
[0003] Motor vehicles equipped with a powertrain system comprising a hydrogen tank and an internal combustion engine coupled to the vehicle's drive wheels are also known. In this case, the hydrogen from the tank is used as fuel to power the internal combustion engine and thus generate engine torque driving the vehicle's drive wheels. The advantages of such a solution are the ability to generate high power output with high efficiency. Furthermore, such an internal combustion engine produces low pollutant emissions compared to an internal combustion engine running on gasoline or diesel fuel.
[0004] Publication CN106541816A also discloses a motor vehicle comprising both a fuel cell and an internal combustion engine, both the fuel cell and the internal combustion engine being intended to consume hydrogen. However, this system has insufficient reliability and performance. In particular, the fuel cell of such a powertrain system can be damaged if it is used at too high a power output with insufficient humidification. Presentation of the invention
[0005] The object of the invention is to provide a powertrain system that remedies the above disadvantages and improves upon known prior art powertrain systems.
[0006] More specifically, a first object of the invention is a more efficient powertrain system that preserves the good condition of a fuel cell. Summary of the invention
[0007] The invention relates to a powertrain system for a motor vehicle, comprising: - a tank designed to hold hydrogen, - a fuel cell designed to produce an electric current by chemical reaction between hydrogen from the tank and oxygen, - an internal combustion engine designed to produce driving torque and water by chemical reaction between hydrogen from the tank and oxygen, - a first humidifier configured to humidify oxygen-rich air entering the fuel cell, and - a first hydraulic line connecting an exhaust outlet of the internal combustion engine to the first humidifier to supply the first humidifier with water from the chemical reaction between hydrogen and oxygen in the internal combustion engine.
[0008] The powertrain system may further include an electric motor for producing drive torque, the electric motor being intended to be powered directly or indirectly by an electric current produced by the fuel cell. The powertrain system may, in particular, include an electrochemical battery intended to be recharged by an electric current produced by the fuel cell, and the electric motor may be intended to be powered by an electric current from the electrochemical battery.
[0009] The powertrain system may include a second humidifier configured to humidify oxygen-laden air entering the fuel cell, and a second hydraulic line connecting an air outlet of the fuel cell to the second humidifier to supply the second humidifier with water resulting from the chemical reaction between hydrogen and oxygen in the fuel cell.
[0010] The second humidifier may include a humidified air outlet connected to an air inlet of the first humidifier.
[0011] The first hydraulic line can be equipped with a heat exchanger intended to reduce the temperature of the gases circulating in the first hydraulic line.
[0012] The first hydraulic line can be equipped with a liquid water separator configured to discharge water in liquid form into the first hydraulic line.
[0013] The first hydraulic line can be equipped with a valve comprising an inlet connected to the exhaust outlet of the internal combustion engine, a first outlet opening to the outside of the powertrain system, and a second outlet connected to the first humidifier.
[0014] The invention also relates to a method of controlling a powertrain system as defined above, the control method comprising: - detecting a need to humidify a membrane of the fuel cell, then - automatically controlling the valve so as to direct water produced by the combustion engine towards the first humidifier.
[0015] The control method may include, prior to the detection of a need to humidify the membrane of the fuel cell, a phase during which the internal combustion engine is stopped, then, following the detection of a need to humidify the membrane of the fuel cell, an activation of the internal combustion engine to obtain water intended to supply the first humidifier, the internal combustion engine being decoupled from any drive wheel.
[0016] The invention also relates to a motor vehicle comprising a powertrain system as defined above. Presentation of the figures
[0017] These objects, features and advantages of the present invention will be described in detail in the following description of a particular embodiment, given by way of non-limiting example, with reference to the accompanying figures, among which:
[0018] Fig. 1 is a schematic view of a powertrain system according to one embodiment of the invention.
[0019] Fig. 2 is a schematic view of a fuel cell of the powertrain system. Detailed description
[0020] Figure 1 schematically illustrates a powertrain system 1 for a motor vehicle according to an embodiment of the invention. The powertrain system 1 It can, for example, be intended to equip a passenger car, a commercial vehicle, a truck, or even a bus. The powertrain system 1 is designed to provide mechanical torque to rotate the vehicle's drive wheels to move the vehicle forward (or backward). To this end, the powertrain system 1 includes at least one rotating shaft 2 intended to be coupled to the vehicle's drive wheels.
[0021] The powertrain system 1 comprises two motors: on the one hand, the powertrain system 1 comprises an electric motor 3, that is to say, a motor intended to be supplied with electrical energy to produce a rotational torque. On the other hand, the powertrain system 1 comprises an internal combustion engine 4, that is to say, an engine capable of transforming the energy produced by the combustion of a gas into a rotational torque.
[0022] According to the embodiment presented, the electric motor 3 and the internal combustion engine 4 are coupled to the same rotating shaft 2, itself mechanically connected to two drive wheels (front or rear), or even to four drive wheels of the vehicle. In an alternative embodiment, the electric motor 3 and the internal combustion engine 4 could be coupled to different drive wheels. For example, the electric motor 3 could be coupled to the front drive wheels and the internal combustion engine 4 could be coupled to the rear drive wheels, or vice versa. In one embodiment, the torques produced by the two motors 3 and 4 are intended to be added together to obtain a higher resulting torque. Alternatively, the powertrain 1 could be configured so that only one of the two motors 3 or 4 drives the vehicle's drive wheels at any given time.
[0023] Furthermore, the powertrain system 1 includes a hydrogen tank 5 (in particular in the form of dihydrogen). The hydrogen contained in the tank 5 is intended to be used directly or indirectly as an energy source to operate the engines 3 and 4. The tank 5 may, for example, take the form of one or more cylinders carried on board the vehicle. The hydrogen may be stored under pressure in the tank 5.
[0024] The internal combustion engine 4 comprises a set of combustion chambers 6, for example three combustion chambers as shown in [Fig. 1], or alternatively any other number of combustion chambers. The internal combustion engine 4 includes a first inlet 41 for supplying hydrogen to each combustion chamber 6. The first inlet 41 is connected to the reservoir 5 by a hydraulic line. The internal combustion engine 4 may include hydrogen injection devices capable of injecting a given quantity of hydrogen at a precise time into each combustion chamber. The internal combustion engine 4 also includes a second inlet 42 for supplying Oxygen-rich air (particularly in the form of dioxygen) is supplied to each combustion chamber. The second inlet 42 can be a simple air intake from the air surrounding the powertrain 1, since ambient air naturally contains a significant proportion of oxygen. Advantageously, as shown in [Fig. 1], the second inlet of the internal combustion engine 4 is equipped with an air filter 43 and / or an air compressor 44, in particular an air turbocharger. Each combustion chamber 6 can also be equipped with an ignition device such as a spark plug. Each combustion chamber is thus intended to be the site of the following exothermic chemical reaction: 2H2 + O2 → 2H2O + energy The energy generated by this chemical reaction allows a piston to move within the combustion chamber. The movement of each piston causes the rotation of a crankshaft attached to the rotating shaft 2, via a connecting rod.
[0025] In addition to energy production, the combustion of hydrogen also produces water (H2O). The water is mixed with the exhaust gases and expelled from the internal combustion engine 4 through an exhaust outlet 45. The exhaust gases therefore consist mainly of oxygen-depleted air and water, particularly in the form of vapor. As we will see later, the water produced by the internal combustion engine 4 will be advantageously used to improve the operation of the powertrain system 1. Furthermore, the kinetic energy of the exhaust gases from the combustion engine can be used to drive the air compressor 44.
[0026] The powertrain system 1 also includes a fuel cell 7. The fuel cell 7 is an electrochemical generator that produces an electrical voltage through the oxidation of a reducing fuel (in this case, hydrogen) at one electrode, coupled with the reduction of an oxidant (in this case, oxygen) at the other electrode. A fuel cell therefore operates in a completely different way from an internal combustion engine, since it is designed to produce an electrical current, and not a mechanical force or torque.
[0027] The fuel cell 7 is advantageously of the "proton exchange membrane fuel cell" type, also known as a "PEMFC". The fuel cell 7 comprises an anodic circuit having a first inlet 11 for supplying hydrogen and a first outlet 12 for removing excess hydrogen. The fuel cell 7 also comprises a cathodic circuit having a second inlet 13 for supplying oxygen-rich air and a second outlet 14 to evacuate oxygen-depleted air and water.
[0028] The fuel cell 7 comprises a stack of cells in series, generally referred to by the English term "stack". Figure 2 illustrates one embodiment of a cell of the fuel cell 7. Each cell comprises an anode 15 in contact with the anodic circuit, a cathode 16 in contact with the cathodic circuit, and a membrane 17 separating the anode 15 and the cathode 16. The membrane 17 is permeable to protons (H+) but impermeable to electrons. The anode 15 and the cathode 16 of each cell are connected in series to an electrical circuit 18.
[0029] When hydrogen and oxygen are supplied to the fuel cell 7 respectively through the first inlet 11 and the second inlet 13, an oxidation reaction of hydrogen occurs on the one hand at the anodic circuit, the chemical formula of which is: H2 2H* 4- 26' On the other hand, H+ protons cross the membrane 17 of each cell and combine with electrons and oxygen to form water molecules according to the following chemical reaction: 4H+ 4µg' + O2 2 H2O The anode of each cell thus reaches a negative electrical potential, while the cathode of each cell reaches a positive electrical potential. This creates a potential difference between the anode and cathode of each cell. Since the cells are connected in series, the potential differences between their anode and cathode are additive. This allows us to establish an electrical voltage of several hundred volts across the terminals of the electrical circuit 18. As we will see later, the electrical current produced by the fuel cell can be used to directly power the electric motor 3 and / or to recharge an electrochemical battery. In [Fig. 2], the path of hydrogen is indicated by the first arrow Fl, the path of air by the second arrow F2, and the path of protons H+ by the third arrow F3.
[0030] The first inlet 11 of the fuel cell 7 and the first inlet 41 of the internal combustion engine 4 are therefore both hydraulically connected to the tank 5. The powertrain system 1 includes a valve 8 comprising an inlet connected to the tank 5, a first outlet connected to the first inlet 41 of the internal combustion engine, and a second outlet connected to the first inlet 11 of the fuel cell. The valve 8 can be controlled so as to supply hydrogen only to the fuel cell. fuel or only the internal combustion engine or simultaneously the fuel cell and the internal combustion engine.
[0031] As a note, the excess hydrogen at the first outlet 12 can advantageously be reinjected into the fuel cell 7 through the first inlet 11 by a recirculation unit 19, for example a pump.
[0032] The membrane 17 may be, for example, a polymer membrane. In one embodiment, the membrane 17 comprises perfluorinated and polyfluorinated alkyls (PFAS). The membrane 17 may, for example, be a NAFION® or equivalent membrane. In another embodiment, the membrane 17 may comprise a hydrocarbon polymer without PFAS. These membranes have the advantage of being more resistant to high temperatures. In particular, they can withstand temperatures of around 100°C to 150°C, which allows the fuel cell to operate at a higher temperature.
[0033] The membrane 17 must perform several functions: it must conduct hydrogen ions (protons), but not electrons, which would create a short circuit in the fuel cell. The membrane 17 must also prevent the passage of gases from one side of the fuel cell to the other, to avoid the phenomenon known as "gas crossover." Finally, the membrane must withstand a reducing environment at the anode and, at the same time, an oxidizing environment at the cathode. To function correctly, the membrane 17 must be moistened. A moisture deficit in the membrane could lead to its damage or even its destruction. In particular, the higher the operating power of the fuel cell 7, the more the membrane 17 needs to be moistened.Thus, when it is desired to increase the electric current produced by the fuel cell, it is necessary to increase the humidity level of the air entering the fuel cell through the second inlet 13.
[0034] Advantageously, according to the invention, the water produced by the combustion of hydrogen in the internal combustion engine 4 is advantageously used to humidify the oxygen-rich air entering the fuel cell. Thus, the membrane 17 can remain sufficiently moist to ensure the proper functioning of the fuel cell 7, even when the latter is operating at full power.
[0035] To this end, the powertrain system 1 includes a first humidifier 21 positioned upstream of the second inlet 13, and a first hydraulic line 22 connecting the exhaust outlet of the internal combustion engine 4 to the first humidifier 21. The first hydraulic line 22 is adapted to supply the first humidifier 21 with water produced by the chemical reaction between hydrogen and oxygen in the internal combustion engine 4. The first humidifier 21 therefore includes a first air inlet, a second inlet for a water-enriched gas from the internal combustion engine 4, and an outlet for humidified air. The outlet of the first humidifier 21 is hydraulically connected to the second inlet 13 of the fuel cell 7.
[0036] As mentioned previously, the powertrain system 1 also includes an electrochemical battery 23, for example of the lithium-ion type, intended to be recharged by an electric current produced by the fuel cell 7. The electric motor 3 is intended to be powered by an electric current from the electrochemical battery 23. This allows the fuel cell 7 to operate at an optimal operating speed, independent of the torque required by the electric motor 3. The fuel cell 7 can thus be electrically connected to the electrochemical battery 23 by means of a first electrical converter 24, in particular of the DC / DC type. The electrochemical battery 23 can be electrically connected to the electric motor 3 by means of a second electrical converter 25, in particular of the DC / AC type.The first converter 24 can also be directly connected to the second converter 25 so that the electric current produced by the fuel cell 7 is directly consumed by the electric motor 3. According to an alternative embodiment of the invention, the powertrain system 1 could be without an electrochemical battery 23. The electric motor 3 would then be powered directly by an electric current from the fuel cell, without prior storage of the electrical energy produced by the fuel cell in chemical form. In this scenario, the two converters 24, 25 could be replaced by a single converter, in particular of the DC / AC type, interposed between the fuel cell 7 and the electric motor 3.
[0037] Furthermore, the powertrain system 1 advantageously includes a second humidifier 26 for humidifying the oxygen-rich air entering the fuel cell 7. Like the first humidifier 21, the second humidifier 26 includes a first air inlet, a second inlet for a water-enriched gas, and an outlet for humidified air. The second humidifier 26 differs from the first humidifier 21 in that it uses water produced by the operation of the fuel cell 7, and not water produced by the operation of the internal combustion engine 4. Thus, the powertrain system 1 includes a second hydraulic line 27 connecting the second outlet 14 of the fuel cell to the second humidifier to supply the second humidifier 26 with water. The second humidifier 26 further improves the humidification of the air entering the fuel cell through the second inlet 13.
[0038] According to the embodiment presented, the first humidifier 21 is positioned downstream of the second humidifier 26. The outlet of the second humidifier 26 is therefore hydraulically connected to the first air inlet of the first humidifier. 21. The second humidifier 26 includes an air inlet from the environment outside the drive system 1. The air inlet of the second humidifier 26 may be a simple air inlet from the air surrounding the drive system. Advantageously, as shown in [Fig. 1], the air inlet of the second humidifier 26 is equipped with an air filter 29 and / or an air compressor 30, in particular an electric air compressor.
[0039] According to a first embodiment, the positions of the first humidifier 21 and the second humidifier 26 could be reversed: the second humidifier could be positioned downstream of the first humidifier and the first humidifier could be connected directly to the second air intake device 28. According to a second embodiment, the powertrain system 1 could comprise a single humidifier including a first inlet hydraulically connected to the second air intake device 28, a second inlet for a water-enriched gas from the exhaust outlet of the internal combustion engine 4, and a third inlet for a water-enriched gas from the second outlet 14 of the fuel cell 7.
[0040] Advantageously, the first hydraulic line 22 is equipped with a heat exchanger 31 for reducing the temperature of the exhaust gases circulating in the first hydraulic line 22. This prevents the humidification of the air entering the fuel cell from causing a rise in the fuel cell's temperature. The heat exchanger 31 can, for example, cooperate with a cooling circuit onboard the vehicle and / or include cooling fins capable of dissipating heat into the air surrounding the powertrain system 1.
[0041] Furthermore, the first hydraulic line 22 is also equipped with a liquid water separator 32 configured to discharge the water in the liquid state present in the first hydraulic line 22. The separator 32 is advantageously positioned downstream of the heat exchanger 31 and thus allows the condensed water following the cooling of the gases in the heat exchanger 31 to be discharged. Thus, only water in the vapor state feeds the first humidifier, which improves its operation.
[0042] In order to adjust the quantity of water from the internal combustion engine 4 delivered to the first humidifier 21, the first hydraulic line 22 is advantageously equipped with a first valve 33 comprising an inlet connected to the exhaust outlet of the internal combustion engine 4, a first outlet opening onto the air surrounding the powertrain system 1, and a second outlet connected to the first humidifier 21. The valve can be controlled in a first position in which it directs the exhaust outlet of the internal combustion engine towards its first outlet, or in a second position in which it directs the exhaust outlet of the internal combustion engine to its second outlet. The first valve 33 is advantageously a solenoid valve. It is capable of being automatically controlled by an electronic control unit on board the vehicle so as to switch it to its first or second position.
[0043] According to a simplified embodiment, the first valve 33 can be a binary-controlled valve: the gases are either directed completely out of the drive system 1 or completely towards the first humidifier 21. According to an improved embodiment, the first valve 33 can be a proportional valve. Such a valve allows for finer adjustment of the quantity of gas entering the first humidifier 1.
[0044] When the fuel cell membrane 17 needs to be moistened, the first valve 33 can be actuated to direct all or part of the exhaust gases from the internal combustion engine 4 to the first humidifier 21. The need to humidify the fuel cell membrane 17 can be detected by means of suitable sensors connected to the electronic control unit, for example, a temperature sensor and / or a humidity sensor. Alternatively or in addition, the need to humidify the membrane 17 can be detected by a calculation, for example, an analysis of the fuel cell's operating point.The electronic control unit can, for example, control the first valve 33 so that it directs the exhaust gases to the first humidifier 21 when the power of the fuel cell exceeds a first predefined value and / or when the temperature of the fuel cell exceeds a second predefined value.
[0045] According to an original operating mode, the internal combustion engine 4 can also be activated exclusively for the purpose of obtaining humid exhaust gases to supply the first humidifier 21. In this case, the torque generated by the internal combustion engine 4 is not used to drive the vehicle's drive wheels. A disengagement mechanism can be provided for this purpose. While such an operating mode does generate a loss of hydrogen by running the internal combustion engine without a load, it allows the membrane 17 of the fuel cell to be humidified. Humidifying the membrane 17 thus prevents damage to or destruction of the fuel cell in critical situations.
[0046] Similarly, in order to adjust the quantity of water from the fuel cell 7 delivered to the second humidifier 26, the second hydraulic line 27 is advantageously equipped with a second valve 34 comprising an inlet connected to the second outlet of the fuel cell 7, a first outlet opening to the outside of the powertrain system 1, and a second outlet connected to the second Humidifier 26. The second valve 34 can also be a binary valve or a proportional valve. The control of the second valve 34 can be analogous to the control of the first valve 33.
Claims
Demands
1. Powertrain system (1) for a motor vehicle, comprising: - a tank (5) for holding hydrogen, - a fuel cell (7) for producing an electric current by chemical reaction between hydrogen from the tank and oxygen, - an internal combustion engine (4) for producing drive torque and water by chemical reaction between hydrogen from the tank and oxygen, - a first humidifier (21) configured to humidify oxygen-laden air entering the fuel cell, and - a first hydraulic line (22) connecting an exhaust outlet of the internal combustion engine to the first humidifier to supply the first humidifier with water from the chemical reaction between hydrogen and oxygen in the internal combustion engine.
2. Powertrain system according to the preceding claim, characterized in that it further comprises an electric motor (3) intended to produce a drive torque, the electric motor being intended to be powered directly or indirectly by an electric current produced by the fuel cell (7), in particular in that the powertrain system comprises an electrochemical battery (23) intended to be recharged by an electric current produced by the fuel cell and in that the electric motor is intended to be powered by an electric current from the electrochemical battery.
3. Powertrain system according to any one of the preceding claims, characterized in that it comprises a second humidifier (26) configured to humidify oxygen-laden air entering the fuel cell, and a second hydraulic line (27) connecting an air outlet (14) of the fuel cell to the second humidifier to supply the second humidifier with water from the chemical reaction between hydrogen and oxygen in the fuel cell.
4. Powertrain system according to the preceding claim, characterized in that the second humidifier (26) comprises a humidified air outlet connected to an air inlet of the first humidifier (21).
5. Powertrain system according to any one of the preceding claims, characterized in that the first hydraulic line (22) is equipped with a heat exchanger (31) intended to reduce the temperature of the gases circulating in the first hydraulic line.
6. Powertrain system according to any one of the preceding claims, characterized in that the first hydraulic line (22) is equipped with a liquid water separator (32) configured to discharge water in the liquid state into the first hydraulic line.
7. Powertrain system according to any one of the preceding claims, characterized in that the first hydraulic line (22) is equipped with a valve (33) comprising an inlet connected to the exhaust outlet of the internal combustion engine (4), a first outlet opening to the outside of the powertrain system, and a second outlet connected to the first humidifier (21).
8. A method for controlling a powertrain system according to the preceding claim, characterized in that it comprises: - detecting a need to humidify a membrane (17) of the fuel cell (7), then - automatically controlling the valve (33) so as to direct water produced by the combustion engine towards the first humidifier.
9. A control method according to the preceding claim, characterized in that it comprises, prior to the detection of a need to humidify the membrane (7) of the fuel cell (4), a phase during which the internal combustion engine (4) is stopped, and then, following the detection of a need to humidify the membrane (17) of the fuel cell, an activation of the internal combustion engine to obtain water intended to supply the first humidifier, the internal combustion engine being decoupled from any drive wheel.
10. Motor vehicle comprising a powertrain system according to any one of claims 1 to 7.