FR3119936A1 - FUEL CELL AND BATTERY HYBRID POWER SYSTEM - Google Patents

Abstract

The invention relates to an electronic control system for a hybrid power supply by fuel cell (FC) and by battery (B) for a motor vehicle, the system comprising - a fuel cell (FC) power supply module,- a battery power module (B),- an inverter (O) and a motor (M),- at least one switching means (C) configured to connect the fuel cell (FC) or the battery (B), - a computer module (µ) configured to estimate a motor power (Pm) requested by the motor (M), and to control said switching means (C) towards the fuel cell (FC) or the battery (B) as a function of motor power (Pm), fuel cell power (FC) and/or battery power (B). The invention further relates to a method, a program and a vehicle based on such a system. Fig. 1

Description

HYBRID FUEL CELL AND BATTERY POWER SYSTEM

The invention relates to the field of devices and systems for electronic control of a hybrid power supply by fuel cell and by battery. This system is particularly suitable for powering an electric vehicle traction motor.

This type of system generally comprises a complex assembly with nested circuits and numerous components. In this assembly, there is a fuel cell power supply module comprising a fuel cell. This module is connected to the motor in order to supply it. In addition, there is a battery power module including a battery. This module is connected to the motor in order to supply it.

The electronic systems proposed in the prior art are not satisfactory because the nested complex circuits have risks of faults and breakdowns. These systems involve direct current converters (DCDC type) between the battery and the motor and/or between the fuel cell and the motor. The converters must be sized accordingly, usually on 40 to 80 kW. The more power the converter requires, the rarer it is, which complicates the production of this type of electronic system.

In addition, switching a power supply involves a control architecture of several on-off switches, with the same risk of a control fault.

Moreover, these systems do not sufficiently combine the two feeding modes so that an improvement seems possible.

Thus, a first objective to propose simplified circuits so as to significantly limit the risks of faults and breakdowns.

A second objective is to simplify the control architecture to have a control allowing easy and fast switching from one power supply to another.

A third objective is to propose an assembly that better combines the two power supply modes.

To achieve these objectives, the invention proposes an electronic control system for a hybrid power supply by fuel cell and by battery for a motor vehicle, the system comprising
- a fuel cell power supply module comprising a fuel cell,
- a battery power supply module comprising a battery,
- a motor connection module comprising an inverter and a motor,
- at least one switching means configured to connect the motor connection module alternatively to the fuel cell power supply module, or to the battery power supply module,
- a computer module configured to estimate an engine power requested by the engine, and to control said means of switching to one or the other power supply module depending on the one hand on the engine power, and d on the other hand the power of the fuel cell and/or the power of the battery.

Advantageously, the layout of the system according to the invention is simplified. Thus, it significantly limits the risk of faults and breakdowns. The system ensures that only one power supply is connected to the motor at a time and never both at the same time.

According to one aspect, said switching means is a switch having a first position for connecting the fuel cell power supply module, and a second position for connecting the battery power supply module. Advantageously, having only two switching positions simplifies switching control from one power supply to another and limits the risk of control faults.

In another aspect, the battery power module is connected to the fuel cell power module by including a DC converter module disposed between the battery and the fuel cell. Advantageously, this makes it possible to use the battery to recharge the battery when powered by the battery.

According to other aspects taken in isolation, or combined according to all technically feasible combinations:
- the computer module is configured to compare the engine power demanded by the engine to at least one power threshold, and to control said switching means to the fuel cell power module if the engine power is lower than said power threshold, or to the battery power module if the motor power is greater than said power threshold; and or
- the power threshold depends on the power difference between the fuel cell power supply module and the power of the DC converter; and or
- the calculator module comprises a timer so as to control the switching means if said threshold is crossed for more than a determined time; and or
- the computer module is configured to control the inverter so as to cancel the power allocated to the motor during the implementation of a switchover; and or
- the computer module is configured to control the DC converter so as to cancel the power allocated to it during the implementation of a switch.

The invention further relates to a method for electronically controlling a fuel cell and battery hybrid power supply for a motor vehicle, the power supply comprising
- a fuel cell power supply module comprising a fuel cell,
- a battery power supply module comprising a battery,
- a motor connection module comprising an inverter connected to a motor,
the method comprising
- a step for estimating an engine power requested by the engine,
- at least one switching step for controlling a connection switching of the motor connection module alternatively to the fuel cell power supply module, or to the battery power supply module, said control being a function of the power of the battery fuel and/or battery power.

Preferably, the control method further comprises a step for recharging the battery in the event of switching to the battery power supply module, by means of the fuel cell via a connection between the fuel cell power supply modules and battery including a DC converter module disposed between the battery and the fuel cell.

Another object of the invention relates to a computer program comprising program code instructions for the execution of the steps of the control method according to the invention, when said program is running on a computer.

The invention also relates to a motor vehicle comprising
- an electronic control system according to the invention,
- a fuel cell, and
- an inverter and a battery.

The invention will be further detailed by the description of non-limiting embodiments, and on the basis of the appended figures illustrating variants of the invention, in which:
- schematically illustrates an electronic control system according to a first preferred embodiment of the invention; And
- schematically illustrates an electronic control system according to a second preferred embodiment.

The invention relates to an electronic control system for an electric vehicle traction motor power supply M. It is a hybrid power supply by a fuel cell FC and by a battery B.

The electronic control system includes a fuel cell power module. This is an electronic assembly to connect an FC fuel cell to other components to operate the power supply.

By “ module ” is meant an electronic structure comprising connection means between different components. The module may include components not described in the present application, according to the knowledge of those skilled in the art.

The electronic control system further includes a battery power module. This is an electronic assembly to connect a battery B to other components to run the power supply.

The electronic control system further includes an engine connection module. This is an electronic assembly to connect a motor M to a power supply, preferably including an inverter O.

The electronic control system further comprises at least one switching means C. This switching means C is configured to connect the motor connection module alternatively to the fuel cell power supply module, or to the battery power supply module .

Advantageously, the arrangement by the system according to the invention is simplified. Thus, it significantly limits the risk of faults and breakdowns. The system ensures that only one power supply is connected to the motor at a time and never both at the same time.

According to one aspect of the invention, said switching means C is a switch having a first position 1 to connect the fuel cell power supply module, and a second position 2 to connect the battery power supply module. Advantageously, this type of switch can quickly switch between the power supply modules thanks to a simplified assembly avoiding errors or control faults that there could be in the case of the use of open/closed switches. This variant simplifies the production of the control system and limits its maintenance.

The switch can be made electromechanically or purely electronically. Depending on the case, it can have a switching time of around 100ms for electromechanics or a few microseconds for electronics. The switching is not noticeable in use.

The electronic control system further comprises a computer module µ configured to control said switching means C. The computer module µ makes it possible to switch to one or the other power supply module. In the context of the invention, the switching is done according to the power of the fuel cell FC and/or the power of the battery B, with regard to a motor power Pm requested by the motor M.

Thus, the computer module µ is configured to estimate a motor power Pm requested by the motor M. Then, the computer module µ can then control said switching means C to one or the other power supply module for example depending on the power of the fuel cell FC.

Advantageously, the calculator module μ makes it possible to adapt the power requested to the power available in the fuel cell FC or the battery B by means of a simplified and rapid assembly.

According to a variant, the battery power supply module is connected to the fuel cell power supply module by including a DC direct current converter module disposed between the battery B and the fuel cell FC. Such a variant can be illustrated by the .

Advantageously, this variant makes it possible to recharge the battery B in the event of switching to the battery supply module. The recharging is done by means of the fuel cell FC via a connection to the DC direct current converter then to the battery B. In addition, it allows to undersize the electronic control system because the DC converter module needs less power than in the prior art.

Alternatively, the electronic control system can be implemented without a connection between the battery supply module and the fuel cell supply module, and without a DC direct current converter module. One could speak of power supply modules isolated from one another and/or of battery FC and battery B isolated from one another. Such a variant can be illustrated by the . Advantageously, this makes it possible to have more under-sizing of the electronic control system with very good performance.

According to a variant, the control of the switching means is done according to at least one power threshold. For this purpose, the computer module μ is configured to compare the engine power Pm requested by the engine M with such a power threshold. If the threshold is exceeded, the computer module µ can command a switch to the desired power supply module.

Thus, if the motor power Pm is lower than said power threshold, then said switching means C can be switched to the fuel cell power supply module.

Thus, if the motor power Pm is greater than said power threshold, then said switching means C can be switched to the battery supply module.

Preferably, the power threshold depends on the power difference between the fuel cell power supply module and the power of the direct current DC converter.

Some manufacturers provide for an 80kW B battery and a 40kW FC fuel cell. Others offer an opposite configuration. The first configuration is preferred because at high power, battery B is more common and easier to procure, making it easier to produce the power system.

Depending on the configuration, the most powerful supply is requested when the corresponding power requirement arises. In use, the average power is 40kW. In the preferred variant, the corresponding energy comes from the FC fuel cell. When accelerating, for example at a toll gate, maximum power is required. At this time, the corresponding energy comes rather from battery B. In general, the use is 80-90% of the time below the maximum power, for example at around 40-50 kW, therefore powered by the battery FC fuel in the preferred configuration.

In the variation shown, the DC converter can be sized at around 8.8 kW for a functional electronic control system in the preferred configuration. A 40 kW or 80 kW converter is not necessary. This facilitates the production of the electronic control system.

According to a variant, the calculator module µ comprises a timer so as to control the switching means C if said threshold is crossed for more than a determined time. This variant makes it possible not to take account of instantaneous power variations which could generate undesired switchings.

According to a variant, the computer module µ is configured to control the inverter O so as to cancel the power allocated to the motor M during the implementation of a switchover. In addition, according to a variant, the calculator module μ is configured to control the direct current DC converter so as to cancel the power allocated to it during the implementation of a switchover. This prevents electrical faults by reconnecting the M motor or the DC converter after switching.

The invention further relates to a method for electronically controlling a hybrid power supply by fuel cell FC and by battery B for a motor vehicle. The process steps can be actions of the components of an electronic control system as described above.

The power system includes a fuel cell power module including an FC fuel cell. The power system further includes a battery power module including a battery B. The power system further includes a motor connection module including an inverter O connected to a motor M.

The method comprises a step for estimating a motor power Pm requested by the motor M. This step can be carried out by taking into account the degree of depression of the accelerator pedal of the electric vehicle.

The method further comprises at least one switching step for controlling a connection switching of the motor connection module alternatively to the fuel cell power supply module, or to the battery power supply module.

Said command is a function of the power of the fuel cell FC and/or of the power of the battery B.

According to the invention, the method further comprises a step for recharging the battery B in the event of switching to the battery power supply module. This recharging is done by means of the fuel cell FC charging the battery B via a direct current DC converter module. In other words, the DC DC converter module is arranged between the battery B and the fuel cell FC.

Regarding an example based on the variant shown in , generally speaking, the maximum power of the fuel cell FC can be P1, and the voltage V1. Regarding battery B, this can be P2, and the voltage V2. For the DC direct current converter, this can be P3, and for the M motor, Pmax. In the variant illustrated Pmax is strictly less than P2.

Now concerning the control method in this example, if the power demanded by the motor M is less than a certain percentage p of (P1-P3), then the switch C is in position 1, that is to say towards the FC fuel cell.

The DC converter is active and consumes a maximum power equal to P3.

As long as the requested power Pm remains lower than p*(P1-P3), we remain in this position 1. Pm can be estimated according to the degree of depression of the accelerator pedal P.

If the requested power exceeds p*(P1-P3), then the computer module µ sends a command to the inverter O to cancel the power requested by the motor M. In addition, the computer module µ optionally sends a command to the DC converter module to stop sending power to battery B.

The calculator module µ then sends a command to the switch C so that it goes to position 2, that is to say to the battery B. It then sends a command to the inverter O so that it restores the power requested by the engine M.

As long as the power requested remains greater than p*(P1-P3), we remain in position 2.

If the requested power falls below this value, a timer is armed. As long as the timer time has not elapsed, and the power remains below p*(P1-P3), we remain in position 2.

If the power goes back above p*(P1-P3), the timer is stopped.

When the power falls below p*(P1-P3), the timer is reset.

When the power remains below p*(P1-P3) for longer than the timer, the calculator module µ sends a command to the inverter O to cancel the power supplied to the motor M. Then, it sends a command to switch the switch C in position 1.

Then it sends a command to the DC converter to supply power to the DC battery again.

Then, it sends an order to the inverter O so that it restores the power supplied to the motor M.

Alternatively, it is possible to keep the DC converter active when switching to position 2.

Advantageously, this embodiment makes it possible to reduce the power of the DC converter, unlike “conventional” architectures where the power of the DC converter is equal to the power of the fuel cell FC.

The transition time from one state to the other can lead to a loss of traction since during these transitions the power supplied to the engine is cancelled, but for an imperceptible time.

Regarding a similar example based on the variant shown in without DC converter, the power and voltage parameters of stack FC and battery B, as well as motor power are the same as in the previous example, but without any power P3 since there is no of DC converter.

Advantageously, this embodiment makes it possible to further undersize the electronic control system by removing the DC converter.

The invention further relates to a computer program comprising program code instructions for the execution of the steps of a control method as described above, when said program is running on a computer. The program can for example be loaded into the memory of a computer of the computer module µ as described previously.

The invention also relates to a motor vehicle comprising

- an electronic control system as described above,

- a fuel cell (FC), and

- an inverter (O) and a battery (B).

Claims (10)

System for electronically controlling a hybrid power supply by fuel cell (FC) and by battery (B) for a motor vehicle, the system comprising
- a fuel cell power supply module comprising a fuel cell (FC),
- a battery power module comprising a battery (B),
- a motor connection module comprising an inverter (O) and a motor (M),
- at least one switching means (C) configured to connect the motor connection module alternatively to the fuel cell power supply module, or to the battery power supply module,
- a computer module (µ) configured to estimate a motor power (Pm) requested by the motor (M), and to control said switching means (C) towards one or the other power supply module as a function on the one hand the motor power (Pm), and on the other hand the power of the fuel cell (FC) and/or the power of the battery (B). Control system according to claim 1, characterized in that said switching means (C) is a switch having a first position (1) for connecting the fuel cell power supply module, and a second position (2) for connecting the battery power module. Control system according to any one of claims 1 to 2, characterized in that the battery supply module is connected to the fuel cell supply module by including a direct current (DC) converter module disposed between the battery (B) and the fuel cell (FC). Control system according to any one of Claims 1 to 3, characterized in that the computer module (µ) is configured to compare the engine power (Pm) demanded by the engine (M) with at least one power threshold , and for controlling said switching means (C) to the fuel cell power supply module if the motor power (Pm) is lower than said power threshold, or to the battery power supply module if the motor power (Pm) is greater than said power threshold. Control system according to Claim 4, characterized in that the computer module (µ) comprises a timer so as to control the switching means if the said threshold is crossed for more than a determined time. Control system according to any one of claims 1 to 5, in which the computer module (µ) is configured to control the inverter (O) so as to cancel the power allocated to the motor (M) during the implementation of a switch. A control system according to any of claims 1 to 6, wherein the calculator module (µ) is configured to control the direct current (DC) converter so as to cancel the power allocated to it during operation of a switch. Method for electronically controlling a hybrid power supply by fuel cell (FC) and by battery (B) for a motor vehicle, the power supply comprising
- a fuel cell power supply module connected to a fuel cell (FC),
- a battery power supply module connected to a battery (B),
- a motor connection module comprising an inverter (O) connected to a motor (M),
the method comprising
- a step for estimating an engine power (Pm) requested by the engine (M),
- at least one switching step for controlling a connection switching of the motor connection module alternatively to the fuel cell power supply module, or to the battery power supply module,
said control being a function of the power of the fuel cell (FC) and/or of the power of the battery (B). A computer program comprising program code instructions for performing the steps of the control method according to claim 8, when said program is running on a computer. Motor vehicle comprising
- an electronic control system according to any one of claims 1 to 7,
- a fuel cell (FC), and
- an inverter (O) and a battery (B).