FR2958464A1 - METHOD FOR CONTROLLING THE CHARGE OF AN ADDITIONAL ENERGY STORER OF A MICRO-HYBRID PROPULSION VEHICLE AND SYSTEM IMPLEMENTING THE METHOD - Google Patents

Abstract

The subject of the invention is a method for controlling the load of the additional energy store UCAP of a micro-hybrid powered vehicle. The method includes a step of detecting a state of said vehicle (200) from among a plurality of possible states, a first state called a fast driving state being detected when the vehicle speed exceeds a predetermined threshold speed value Vseuil, a second a state being detected when the vehicle is parked, the voltage applied across the UCAP storer being adapted (201, 202) according to the detected state so that it is minimized while ensuring that said storer performs his functions on duty. The invention also relates to a system implementing the method.

Description

The invention relates to a method for controlling the charge of an energy storage device and to a system implementing the method. addition of a vehicle with micro-hybrid propulsion and system implementing the method. It applies to the field of hybrid propulsion vehicles.

1 o Hybrid propulsion vehicles, that is to say combining a heat engine with at least an electric motor, help to minimize fuel consumption and thus contribute to the reduction of greenhouse gas emissions. Systems implementing such a type of propulsion can be classified into several categories representative of their level of hybridization. Thus, the systems belonging to the micro-hybrid category usually comprise in addition to the conventional combustion engine a reversible electric motor. This electric motor is used as a starter and as an alternator, the heat engine being automatically shut off when the vehicle is immobilized. An exemplary architecture of such a system is illustrated in FIG. 1. This exemplary architecture incorporates a reversible alternator 100, a starter 101, a battery 102 and an additional energy storage unit consisting of supercapacitors 103, also known as UCAP 25 in the following description. The battery 102 is for example a 12-volt lead battery. By means of a specific control electronics enabling the control of switches 104, 105, the additional energy storer 103 can be put in series with the battery 102 in order to contribute to the start-up, restart and maintenance of services. the quality of the onboard network 106. Still by controlling said switches 104, 105, the additional energy storer 103 can be put in parallel with the alternator 100 via a voltage converter 107 to ensure its recharging when the engine is running. The UCAP storer 103 can also be connected to the battery 102 via the voltage converter 107 in order to recharge when the motor is stopped. The UCAP storer 103 may also be electrically isolated when its contribution is not required by the system and the system is loaded. As explained above, the additional energy store is therefore usually associated with a switching system 104, 105 for placing in series or in parallel and a voltage converter 107 used for charging. This assembly 108 is highlighted in FIG. 1. Supercapacitors are components whose use is recent in the automotive field. Their use requires a number of intrinsic precautions to avoid damaging them. Among the aging factors affecting these supercapacitors, the terminal voltage and the temperature are preponderant. In particular, high voltage levels induce acceleration of the electrochemical aging of the UCAP storer. The life of the UCAP storer is a determining factor when designing a vehicle using a hybrid propulsion system. Indeed, a car manufacturer usually offers vehicles by committing to their lifespan based on sizing studies and the expertise of suppliers of supercapacitors. One of the design objectives is for the keeper of such a vehicle to replace the UCAP storer as little as possible, for example by providing a system whose service life tends towards the life of the vehicle. typically 15 years.

An object of the invention is in particular to overcome the aforementioned drawbacks. To this end, the subject of the invention is a method for controlling the load of the additional energy store UCAP of a micro-hybrid powered vehicle. It comprises a step of detecting a state of said vehicle from among a plurality of possible states, a first state called fast rolling state being detected when the speed of the vehicle exceeds a predetermined threshold threshold value Vthreshold, a second state being detected when the vehicle is parked, the voltage applied across the UCAP storer being adapted according to the detected state so that it is minimized while ensuring that said storer performs its service functions. According to one aspect of the invention, an optimized UCONS OPTIM load voltage is determined and applied to the UCAP storer when the fast rolling state is detected, said voltage being derived from a UCONS nominal load voltage associated with the UCAP storer, a AU voltage deviation is subtracted from this voltage to obtain the optimum UCONS OPTIM load voltage value. According to another aspect of the invention, the voltage difference AU is determined by using an affine function AU = f (VVEH) such that the difference AU is proportional to the difference between the instantaneous speed VVEH and a threshold of preset speed VVEH STOP allowing the transition to the stop phase. The voltage difference AU is determined, for example, using the expression: AU = K. r l \ 10 (VVEH to VVEH STOP 1. 36 15 YVeh

in which: K is a coefficient materializing the load speed of the UCAP storer expressed in V / s for a capacity expressed in Farads and a charge / discharge current expressed in Amperes; yveh is the statistical average of the braking deceleration of the vehicle; When the parking state is detected, a multi-function motor control computer CMM included in the micro-hybrid vehicle 25 is, for example, partially awake for a sufficient period of time so as to determine an optimized load voltage value UCONS OPTIM taking into account this state. According to one embodiment, the optimized UCONS OPTIM optimized charging voltage value in the parked state is determined according to the SOH state of health of the UCAP storer.

The invention also relates to a micro-hybrid propulsion system comprising at least one additional energy store UCAP. The system comprises means for detecting the state of the vehicle comprising said system from a plurality of possible states, a first state said fast rolling state being detected when the speed of the vehicle exceeds a threshold threshold value V predefined threshold, a second state being detected when the vehicle is parked. The system also comprises means for determining the voltage to be applied across the UCAP storer, said voltage being adapted according to the detected state so that it is minimized while ensuring that said storer performs his service functions. .

Advantageously, the invention slows the aging of the UCAP storer, which reduces the number of failures related to the end of life of said storers. The user of the vehicle thus saves in terms of maintenance and replacement expenses.

Other features and advantages of the invention will become apparent with the aid of the following description given by way of non-limiting illustration, with reference to the appended drawings in which:

FIG. 1 gives an example of a micro-hybrid system; FIG. 2 gives an example of a method for optimizing the life of the UCAP storer in a fast rolling state; FIG. 3 gives an example of a method for optimizing the lifespan of the UCAP storer in the parked state; FIG. 4 represents the statistical distribution of the voltage across the UCAP throughout its lifetime.

The system according to the invention comprises means for determining the states of life during which the UCAP storer is not solicited and will not be solicited during a given period of time as well as means for reducing the voltage at the terminals of said storer when these states are detected. Maintaining a high voltage has adverse consequences on the aging of the UCAP storer. Advantageously, the implementation of the system allows an extension of the life of the storer 35 of additional energy. A micro-hybrid system comprises for example a UCAP storer composed of several supercapacitors in series. It can be composed for example of two supercapacitors, each having a maximum allowable voltage of 2.7V, or 5.4V for both. If this maximum voltage is exceeded, the destruction of said storage can be extremely fast. Thus, the recharge can be limited preferably by a threshold value slightly lower than this maximum value, 5V for example. Moreover, in certain circumstances, a voltage level close to the threshold defined above may be necessary for UCAP 1 o to fully perform its service functions. This is particularly the case when the UCAP storer contributes to start-up / restart services and maintains the quality of the on-board network, which implies repeated charges at voltages close to said threshold. Even if one does not exceed the maximum permissible value of the PFAP, 5.4V in this example, prolonged maintenance at a high voltage level nevertheless has an impact on the life of the storer. Thus, the mere fact of limiting the recharge of the UCAP storer to a threshold voltage proves insufficient with respect to the requirements in terms of lifetime. The UCAP storer is usually used for one-off needs during a vehicle taxi cycle. Thus, it is possible to exploit the states or phases of life during which the UCAP storer is not made to contribute to lowering the voltage at its terminals. In practice, the UCAP storer is requested at the first start of the vehicle, that is to say the start of the vehicle while it is in parked state. The storage UCAP is also requested at each restart, that is to say in phases called stop phases and corresponding for example to a stop in front of a red light. From these states of activity or reloading of the UCAP storer can determine inactivity time intervals during which the UCAP storer is not requested. In the remainder of the description, two types of operating state of the hybrid propulsion system are identified. The first state is called the fast driving state and the second state is called the parking state. The fast driving state corresponds to a state in which the vehicle is in driving situation on road or highway. In this state of operation, a vehicle traveling on the road or motorway will very rarely enter the stop phase. Thus the UCAP storer will not be used to restart. It is then possible to carry out a sensitive discharge of the UCAP storer as soon as the speed exceeds a configurable threshold value and to reload it when the speed returns below this value. For parking status, a vehicle that is about to be parked usually has a fully loaded UCAP storer. As a result, the UCAP storer remains loaded for the duration of the parking, without any real need. Following the principle of the invention, optimized management would consist of substantially unload the UCAP when the vehicle is stopped.

Figure 2 gives an example of a method for optimizing the life of the UCAP storer in fast running state.

Whether in fast running state or not, a voltage set point calculation is continuously performed and adjusted according to the state of the entire electrical chain so that the UCAP storer is always sufficiently loaded to respond to a problem. soliciting, a solicitation for example corresponding to a booster energy to restart the engine after a stop phase. A further adjustment of this setpoint can be implemented so as to unload the UCAP storer by applying a certain voltage deviation to the nominal load voltage. This discharge makes it possible to preserve the lifespan of the UCAP storer.

Advantageously, this voltage drop can be applied in a progressive manner depending on the speed of the vehicle, so that in case of braking the refilling of the UCAP storer is not penalized, said storer having to be subsequently put to use following a stop phase. Thus, in a fast rolling state, the UCONS OPTIM voltage to be applied across the UCAP storer, hereinafter referred to as the optimized voltage setpoint description, can be determined using, for example, three steps. A first step 200 determines what is the state of the vehicle. Thus, if the detected state corresponds to a fast rolling state, an indicator (PR / A of rolling state detection is activated .This indicator corresponds for example to a boolean and can be considered as active when it takes the value 1. For example, the activation of the indicator (PR / A can be determined in the following way: if the vehicle speed VVEH exceeds a threshold value configurable Vthreshold indicating a fast rolling, then (PR / A = 1. If this threshold value is not exceeded, then (PR / A = 0. A second step 201 determines a voltage difference AU corresponding to a voltage drop to be applied to a nominal voltage setpoint UCONS applied across the terminals of the UCAP storer, one of the objectives being to optimize the life of the UCAP storer 1 o This difference in voltage AU is determined by taking into account the value of the indicator (PR / A.

Thus: If (PR / A is active, AU is determined such that AU = f (VVEH); If (PR / A is inactive, AU = 0.

The function f (VVEH) is for example an affine function such that the difference AU is proportional to the difference between the instantaneous speed VVEH and the speed threshold VVEH STOP allowing the passage to the stop phase. The coefficient of proportionality of this affine function can take into account the loading / unloading time of the UCAP storer with respect to the braking time of the vehicle. By way of example, the following expression can be used: DU = K • (VVEH ù VVEH STOP 1) 25 36 YVe h (1) in which: K is a coefficient materializing the load speed of the UCAP storer expressed in V / s for a capacity expressed in Farads and a charge / discharge current expressed in Amperes; yveh is the statistical average of the braking deceleration of the vehicle; the factor 10/36 is used for the conversion of speeds expressed in km / h to speeds expressed in m / s. This is an advantageous example of embodiment, but it could very well have been used, to determine the voltage difference AU, to use another formula, a constant value, a cartography.

A third step 203 determines the UCONS OPTIM optimized voltage setpoint taking into account the difference AU and the rated voltage set point UCONS. The following expression is used for example: UCONS OPTIM = UCONS to AU (2)

Figure 3 gives an example of a method of optimizing the life of the parking storer UCAP. As part of the usual operation of a micro-hybrid propulsion system when the vehicle is parked, the UCAP storer is at a high voltage level when it is useless because it will no longer be solicited before the next start. . In addition, the voltage setpoint is difficult to control because in practice the multifunctional engine control computer 20, usually designated by the acronym CMM, falls asleep when the vehicle is parked. It is no longer possible to calculate a voltage setpoint to be applied to the UCAP storer. The invention proposes to prolong the calculation of the setpoint during a time of partial awakening of the CMM. This partial awakening is of sufficient duration to adjust the voltage of the UCAP storer to a non-detrimental level for its lifetime. However, do not completely unload the UCAP storage because the charging time for the next start must be limited. In the parking state, the optimized voltage setpoint UCONS OPTIM to be applied across the storage unit UCAP can be determined using, for example, two steps. A first step 300 determines whether the vehicle is in a parked state. This detection can be carried out on the basis of a partial wake-up indicator of the CMM calculator RPARTIEL, said indicator taking the value 1 when the CMM computer is awake despite the fact that the vehicle is in a parked state. Thus, if RPARTIEL = 1, a parking phase detection cps indicator is set to active state, i.e. cps = 1 for example. cps is set to inactive otherwise, ie cps = 0 for example. A second step 301 is applied when the cps flag is set to an active state. The setpoint USONS OPTIM can then be determined by using the following expression: USONS OPTIM = US (3) in which: Us is a configurable voltage value, resulting from a compromise allowing optimization of the lifetime of the UCAP storer while guaranteeing an acceptable charging time for the next vehicle start.

By way of example, the value of Us can be determined by using an expression such as: Us = f (SOH) (4) in which: SOH, an acronym derived from the English expression "State Of Health", represents the state of health of the UCAP storer expressed as a percentage, a value of 0% corresponding to an unusable UCAP storer and a value of 100% to a new UCAP storer in perfect working order. SOH is for example estimated in an electronic box dedicated to the UCAP storer and allows in particular to weight the voltage setpoint according to the remaining life of the UCAP. The state of health of the UCAP storer influences the internal characteristics of the UCAP, in particular its internal resistance and its capacity. As a result, the aging also impacts the charging time for start-up. If the cps indicator is set to an inactive state, the setpoint voltage is not optimized and is expressed simply by the expression: USONS OPTIM = USONS (4 Figure 4 shows the statistical distribution of the voltage across the UCAP throughout its lifetime. The right curve 400 represents the statistical distribution of the voltage at the terminals of the UCAP storer when the invention is not used. This voltage is often high, and aging of the UCAP storage is fast. The left curve 401 represents the statistical distribution of the voltage at the terminals of the UCAP storer when the invention is used. The voltage is statistically lower and aging of the UCAP storer will therefore be slowed down.

Claims (7)

CLAIMS 1- A method for controlling the charge of the additional energy storage unit UCAP (103) of a vehicle with micro-hybrid propulsion characterized in that it comprises a step of detecting a state of said vehicle (200, 300) among a plurality of possible states, a first state called fast rolling state being detected when the speed of the vehicle exceeds a predetermined speed threshold value Vseuil, a second state being detected when the vehicle is parked, the voltage applied to the 1 o terminals of the storing UCAP being adapted (201, 202, 301) according to the detected state so that it is minimized while ensuring that said storer performs its service functions. 2. The method as claimed in claim 1, characterized in that an optimized load voltage UCONS_OPTIM is determined and applied (201, 202) to the storage unit UCAP when the fast rolling state is detected, said voltage being deduced from a voltage of UCONS nominal load associated with the UCAP storer, a voltage deviation AU being subtracted from this voltage in order to obtain the optimized load voltage value UCONSOPTIM. 3. The method as claimed in claim 2, wherein the voltage difference AU is determined (202) by using an affine function AU = f (VVEH) such that the difference AU is proportional to the difference between the instantaneous speed VVEH. and a predefined VVEH STOP speed threshold allowing passage to the stop phase. 4. The method as claimed in claim 3, wherein the voltage difference AU is determined by using the expression: (VVEH l (ùVVEH STOP)), in which: K is a coefficient representing the load speed of the storage unit UCAP expressed in V / s for a capacity expressed in Farads and a load / discharge current expressed in Amperes, yveh corresponds to the statistical average of the braking deceleration of the vehicle; 5. Method according to any one of the preceding claims, characterized in that when the parked state is detected, a multifunctional motor control computer CMM included in the micro-hybrid vehicle is partially kept awake for a sufficient period of time. in order to determine an optimized UCONS OPTIM load voltage value taking this state into account. 6. Process according to claim 5, characterized in that the optimized UCONS OPTIM optimized charging voltage value in the parked state is determined (301) as a function of the SOH state of health of the UCAP storer. 7. A micro-hybrid propulsion system comprising at least one additional energy store UCAP characterized in that it comprises means for detecting the state of the vehicle (200, 300) comprising said system from among a plurality of possible states. , a first state said fast rolling state being detected when the speed of the vehicle exceeds a predetermined speed threshold value Vthreshold, a second state being detected when the vehicle is parked, and means for determining the voltage to be applied across the terminals of the vehicle. UCAP storer, said voltage being adapted according to the detected state so that it is minimized while ensuring that said storer performs its service functions. 30