FR2874136A1 - Window regulator or lock`s electrical actuator supply device for motor vehicle, has voltage converter delivering regulated voltage to supply actuator, electrical switch unit to select either battery or electric energy storage units - Google Patents

Abstract

The device has electrochemical super-capacitors or capacitors (4), and a voltage converter (6) regulating an output voltage of a battery (1) and delivering a regulated output voltage (Us) for supplying an electrical actuator (2). An electrical switch unit (8) compares the voltages from the battery and electric energy storage units (5) to select either battery or units (5) when the output voltage attains a preset threshold voltage value. The energy reserve units are constituted of multiple electric batteries such as lithium batteries or nickel metal hydride type electrochemical batteries.

Description

POWER SUPPLY DEVICE FOR ELECTRICAL DEVICES

  The invention relates to a power supply device for electrical actuating devices in motor vehicles. The invention applies in particular to the supply of electric actuators for automobiles having critical or safety functions, for example window lifts or locks, in motor vehicles.

  Already known in the prior art include EP 1130202 which proposes an electronic power reserve component consisting of a supercapacitor forming a rechargeable and compact energy source. During normal use of the vehicle, this electronic component is not requested as long as the main power supply means function normally. These main means then permanently maintain the supercapacitor in charge.

  When, as a result of a failure of the main power supply means, the latter are no longer able to provide electrical energy for the opening of the lock, the power is automatically switched to the supercapacitor which allows the operating a lock for several opening cycles.

  The electric actuators in this type of device must be sized to operate in wide voltage ranges, which requires the realization of powerful actuators, therefore imposing dimensions, showing large dispersions in the response times for the opening of the lock. Moreover, the higher the voltage delivered to the gearmotors, the faster they turn and therefore the more the shocks suffered by the actuators are important. Thus, it has been observed by the applicant that one of the major drawbacks of this type of device lies in the limited service life of the mechanical parts of the actuators due to fatigue phenomena, or wear, related to violent shocks for high voltages, aggravated by the oversizing of said actuators.

  To overcome these disadvantages, conventional solutions can be envisaged by arranging dampers or by achieving an optimal design of the actuator parts. However, these solutions are not fully satisfactory because they respectively require either additional parts, bulky and especially limiting the actuation energy exerted by the actuators is expensive for a relatively low lifetime gain.

  The present invention intends to overcome the disadvantages of the devices of the prior art by proposing a solution which has the particular advantage of being able to be incorporated or added a posteriori to an existing actuator by connecting the object of the invention in series between the actuator and the vehicle power supply.

  The invention relates to a power supply device for electrical actuating devices in motor vehicles, the electrical actuating apparatus being connected to main power supply means and power supply backup means in case malfunction of the main means, these emergency means comprising a power reserve component, characterized in that it comprises at least one voltage regulator means adapted to deliver a regulated output voltage Us for supplying said electrical actuating apparatus.

  The term voltage regulator means in particular a voltage converter or any other means capable of performing the same function. In the same way, the expression regulated output voltage is understood to mean a constant or quasi-constant output voltage, that is to say that the output voltage can vary by 5%, preferably by 2%.

  Furthermore, the prior art supply systems have other problems if a relatively long period of time elapses between the malfunction stop of the main supply means, for example during parking, and the attempt to open the lock. Indeed, when the supercapacitor is discharged, the lock then no longer includes any functional backup means because the supercapacitor in the passive state discharges relatively quickly because of internal leak phenomena.

  To solve this problem, it has been envisaged that the emergency means also comprise electrical energy reserve means connectable to the power reserve component for powering the latter in the case where the main power supply means are lacking.

  In substantially the same manner as for the main power supply means, the power reserve means produce a variable input voltage for the power reserve component, particularly as the reserve resources of energy are discharged.

  Also, the device, according to a particularly advantageous embodiment of the invention comprises electrical energy reserve means connectable to said power reserve component.

  The presence, in accordance with the invention, of the voltage regulator means makes it possible to compensate for the variations in the voltage delivered by the power reserve means.

  Moreover, in this type of system, there is a waiting time before the use of the actuator, or the electrical operating device, because of the necessary charging time of the power reserve means by the means of energy reserve.

  Thus, to solve this additional problem, according to a preferred embodiment of the invention, the device will further comprise at least one electrical switching means adapted to automatically switch the power source of the power reserve means either from the aforementioned main power supply means or from said power reserve means when the voltage from the main power supply means is less than or equal to a determined threshold voltage Useuil .. When the voltage delivered by the means main power supply is equal to Useuil., that is to say that the main power supply means are no longer able to supply the power reserve means, energy reserve means take over by feeding them.

  The tilting is of course reversible, that is to say that the electrical switching means can again switch the power source of the power reserve means to the main power supply means when the voltage from the main power supply means is greater than the determined threshold voltage Useuil .. Thus, as soon as the voltage of the battery becomes greater than the threshold voltage Useuil., for example following the recharging of the battery, the power reserve means are again powered by the main means of feeding. To avoid oscillatory phenomena, the Useuil threshold voltage. will include a hysteresis.

  Thus, in this embodiment, the power supply system is completely uninterruptible, or without interruption, regardless of the environmental conditions, constraints or actuation of the emergency means. Indeed, thanks to the electrical switching means, the power supply will be uninterruptible because the supercapacitor (s) is / are always charged (s), either by the main supply means or by the reserve means of energy so that this charging time is zero or almost zero.

  According to a preferred embodiment, said power reserve component comprises at least one supercapacitor. The advantage of a supercapacitor based power system over an electrochemical accumulator system (NiCd or NiMH) lies in its small size and low weight as well as its ease of use and its service life.

  The invention is described below in more detail, with the aid of figures representing only preferred embodiments of the invention.

  FIG. 1 is a general block diagram of a device according to the invention; FIG. 2 is a more detailed schematic view illustrating the elements of the dipositive device according to the invention.

  Figure 1 shows a device according to the invention comprising all of the elements presented above. Thus, this device consists of an uninterruptible power supply system connected to a vehicle battery 1 and to an electric actuator 2. The electric actuator 2 is connected to control means 3. Block 9 of FIG. combination of a set of elements 4, 5, 6, 7, 8 visible in Figure 2.

  In the following, we have chosen to illustrate the invention in connection with a lock of a motor vehicle which will constitute the electrical device to be powered, or actuator, not shown in the accompanying figures.

  Thus, a lock for a motor vehicle, with electric opening assistance, is connected to an outer handle and an inner handle, for controlling its opening respectively outer or inner. It comprises an electronic card forming an interface for connecting the lock to the main power supply means 1 and to control means 3.

  The lock is therefore connected to the main power supply means 1, generally a battery equipping and supplying the motor vehicle. This battery 1 supplies a locking management electronics which actuates the locking or unlocking of the lock and a power reserve component 4, advantageously a supercapacitor, as well as possibly a signal identification member, generally an RF receiver. , not shown in the accompanying figures. This power reserve component 4 is of course compatible with the power demanded by the actuator 2.

  The power reserve component 4 is charged by the main power supply means 1 and is directly electrically connected to the lock. In case of failure, the electronic card of the lock automatically switches to the component 4 which can allow the operation of the lock during several opening cycles. Of course, as explained above, this is possible in the case where the time between the malfunction of the main supply means 1 and the attempt to actuate the lock is not too long.

  The power reserve component 4 may consist of one or more supercapacitors (s) or capacitor (s) of the electrochemical type. These capacitors, or supercapacitors, can be assembled in pack or soldered on the same printed circuit.

  The device of the invention advantageously comprises a reserve of energy 5 compatible with the required service life as well as with the automotive environment. The energy reserve 5 is connected to the power reserve component 4 so that the latter 4 is supplied for charging normally by the main power supply means, that is to say when the main power supply means 1 operate correctly, and exceptionally by the energy reserve means 5.

  This energy reserve 5 may consist of one or more lithium batteries coiled (s) or spiral (s) according to the characteristics of the actuator. These batteries can be assembled in a compact package, or packs, or soldered on the same printed circuit.

  In general, it may also be provided that the energy reserve means consist of at least one electric battery or accumulator or an electrochemical accumulator, for example of the NiMH type. Nevertheless, the advantage of lithium batteries over an accumulator system remains their high cell voltage, resulting in a reduced number of cells, as well as their wide operating temperature range compatible with the automotive environment.

  The device of the invention is characterized in the first place in that it comprises a voltage regulator means 6, in this case a voltage converter, which can be a set referred to as a chopper, generally comprising a low-loss diode, for example example of a Schottky type, and a coil, a controlled switch which may consist of either a single component or a field effect transistor, for example of the MOS type, and a control component, for example a microcontroller and a feedback loop generally performed by resistors. This feedback loop obviously makes it possible to ensure the correct operation of a regulator by measuring the physical quantity that one seeks to regulate. This voltage regulator means 6 is assembled on a printed circuit. Thus, in the device of the invention, the power reserve component 4, the energy reserve means 5 and the voltage converter 6 may be fixed on the same electronic card, for example a printed circuit, so as to form a complete and compact system.

  The device represented in FIG. 2 also comprises a Schottky-type low-loss diode 7 connected to the main power supply means 1, that is to say between these means 1 and the voltage converter 6, as well as an electrical switching means 8 which compares the voltage at the cathode of this diode 7, that is to say the voltage coming from the main power supply means 1, with the voltage coming from the energy reserve means 5 so as to automatically select one or the other power supply means of the power reserve component 4, namely either the main power supply means 1 or the reserve means 5 when the output voltage of the The main power supply means 1 reaches a determined minimum threshold voltage value Useuil, for example about 6 volts. Indeed, the main power supply means 1, that is to say usually the battery, typically deliver a voltage of between 9 and 16 volts while the energy reserve means 5 deliver a lower voltage, for example between 4 and 6 Volts if we associate two batteries of 3 Volts each. Thus, in this case, the threshold voltage Useuil. is equal to the maximum voltage delivered by the reserve means 5. It is also possible to envisage that the threshold voltage Useu; is equal to the voltage delivered by the energy reserve means 5, regardless of the value of this voltage.

  It should be noted that the lower operating voltage value for the battery 1, ie 9 V, does not allow the vehicle to start but still allows the supply of electronic components of small size and power. On the other hand, the voltage from the energy storage means 5 also varies, firstly during the life of said means 5 but also because of environmental factors such as changes in temperature.

  In the present example, the device of the invention comprises a single diode 7 but it may be provided several diodes 7, located between the main power supply means 1 and the voltage converter 6. The Schottky diode here plays its usual function , that is to say identical to that of a normal diode, in on and off state, with higher operating characteristics, in particular at the lower blocking voltage.

  The device of FIG. 2 also comprises a voltage regulator means 6, or voltage converter, which may be produced according to a Single Ended Primary Inductance Converter (SEPIC) topology or a Buck-Boost topology. The SEPIC topology allows the use of a transformer instead of two coils, reducing the size and weight of the assembly on the electronic board. The output voltage Us of the converter 6 is directly intended for the power reserve component 4, the voltage US being regulated, or fixed, for example at approximately 11.5 volts in order to preserve the performance of the component 4.

  According to a possibility offered by the invention, the device may also comprise means for controlling the voltage arriving at the power reserve component 4 as a function of the ambient temperature, in order possibly to modify the output voltage U ,, ,, t. In this case, the device of the invention will comprise a means for measuring / controlling the temperature, such as a PTC thermistor (Positive Temperature Coefficient) or a thermocouple.

  This variable resistance with the temperature may advantageously be inserted into the feedback loop of the voltage regulator means 6.

  This will therefore allow the system to automatically adapt the output voltage Us according to the ambient temperature in order to preserve the performance of the component 4. Thus, the feedback loop of the voltage regulator means will comprise a resistor whose variation in value in Temperature function is known and mastered.

  The device of the invention is not limited to the embodiment described here and may in particular be modified to obtain different architectures according to the security and cost requirements: power reserve 4 integrated to the actuator 2, reserve 5 centralized energy, integrated system, etc. Furthermore, although the embodiment described above has the device according to the invention comprising means of energy reserve 5, it is clear that these energy reserve means 5 are not essential; the voltage regulating means 6 acting a priori on the main power supply means 1, and possibly also on the energy reserve means 5.

Claims (10)

  1. Power supply device for electrical actuating devices in motor vehicles, the electric actuating apparatus being connected to main power supply means (1) and to power supply back-up means in case of malfunction main means (1), these emergency means comprising a power reserve component (4), characterized in that it comprises at least one voltage regulator means (6) adapted to deliver a regulated output voltage US to power said electric actuating apparatus.   2. Device according to claim 1, characterized in that said voltage regulator means (6) regulates the voltage from said main power supply means (1).   3. Device according to any one of claims 1 or 2, characterized in that it comprises power reserve means (5) connectable to said power reserve component (4).   4. Device according to claim 3, characterized in that the power reserve means (5) are connected to said voltage regulator means (6).   5. Device according to claim 3 or 4, characterized in that it comprises at least one electrical switching means (8) adapted to automatically switch the power supply source of the electrical energy reserve means (5), either from said main power supply means (1) or from said power reserve means (5) when the voltage from the main power supply means (1) is less than or equal to a specified threshold voltage Useu; , ..   6. Device according to any one of claims 3 to 5, characterized in that said energy reserve means (5) consist of at least one electric battery, for example one or more lithium batteries, or an accumulator electric or an electrochemical accumulator, for example of the NiMH type.   7. Device according to any one of claims 3 to 6, characterized in that the power reserve component (4), the energy reserve means (4) and the voltage regulating means (6) are fixed on the same electronic card.   8. Device according to any one of the preceding claims, characterized in that the voltage regulating means (6) is made according to a SEPIC topology.   9. Device according to any one of the preceding claims, characterized in that the aforesaid power reserve component (4) comprises at least one supercapacitor.   10. Device according to any one of the preceding claims, characterized in that the aforesaid regulated output voltage Us is approximately equal to 11.5 volts.