EP1574920A1 - Method for managing the time information display in an ectronic device - Google Patents

Abstract

A method of managing a display of time information in an electrical apparatus comprising an internal time clock and a time-based clock generated by the power supply network of the apparatus, includes a step of detecting (E30) of a powering of the electrical apparatus, a step of reading (E31) a time information stored in an internal time clock, a step of updating (E32) of the clock time base generated by the power supply network by the time information stored in the internal time-based clock and a display step (E32) of this time information. Use in particular for updating the clock based on external time after power failure. <IMAGE>

Description

The present invention relates to a method for managing a display hourly information in an electrical appliance.

It also relates to an electrical apparatus adapted to implement the display management method according to the invention.

In general, the invention relates to electrical appliances equipped with a time display system. Generally, these displays are adapted to indicate the current time, but also the duration of a process implemented in the electrical apparatus, or a programmed duration to the expiration of which the operation of the electrical apparatus will be sets off.

More particularly, the present invention relates to apparatus domestic electrical appliances of the type cooking appliance, and in particular oven electric or microwave oven, or refrigerator. This domain application is of course not limiting.

When more than one electrical appliance is equipped with a display a time information, it is difficult to synchronize the time indication current level of the display of each device.

In particular, at the time of installation of an electrical appliance, It is possible to update the current time on each device. The synchronization in time of this display is however difficult to obtain.

The display of a time information on an electrical device is made from information given by a built-in clock electric.

Clocks fitted to such devices may be classified in two categories: time-based clocks and time-based clocks external time, for example generated by the power supply network of the device.

The clocks based on internal time are associated with a base of embedded time, that is to say integrated into the electrical device. They can besides being associated with an autonomous power supply, allowing the clock operation regardless of the power supply of the device. Typically, an internal time base can be made of a quartz, or an electronic oscillator type 555.

These time-based clocks have the advantage of being inexpensive and allow good accuracy in the time display. However, they generally have a temperature drift that can reach more or less 100 ppm for a rise of 50 ° C.

Time-based clocks generated by the power network usually use the frequency of the power grid that is relatively stable (plus or minus 20 ppm). This network frequency electrical appliance being common to all the electrical appliances connected to this network, it is is possible after common initialization, to maintain synchronized display hourly level of each electrical device using such a clock to external time base.

However, in case of power failure, time information is lost so that it is necessary to day time at each electrical device and synchronize this update. Moreover, these time-based clocks do not allow not know the duration of the power failure.

The present invention aims to solve the disadvantages mentioned above and to propose a method for managing a display of information time set in an electrical appliance using the electricity network, to better manage a power cut.

For this purpose, the invention aims at a method of managing a display of a hourly information in an electrical apparatus comprising a clock based internal time and a time-based clock generated by the network power supply of the device.

• détection d'une mise sous tension de l'appareil électrique ;
• lecture d'une information horaire mémorisée dans une horloge à base de temps interne ;
• mise à jour de l'horloge à base de temps générée par le réseau d'alimentation électrique par l'information horaire mémorisée dans l'horloge à base de temps interne ; et
• affichage de ladite information horaire de l'horloge à base de temps générée par le réseau d'alimentation électrique.

According to the invention, this management method comprises the following steps:

• detecting a power-up of the electrical apparatus;
• reading a time information stored in an internal time clock;
• updating the time-based clock generated by the power supply network with the time information stored in the internal time-based clock; and
• displaying said time information of the time-based clock generated by the power supply network.

This management method thus allows during power-up of an electrical appliance, to obtain an automatic display of information schedule stored in an internal time clock and update in the external time-based clock.

In particular, after a power failure, when voltage of the electrical apparatus, a time information whose update has been maintained during power failure through time-based clock internal, is displayed on an electrical device.

According to one embodiment of the invention, the time information of the internal time-based clock is updated at least one instant predetermined by time-based time information generated by the network power supply.

The time information based on internal time can thus be set to day and synchronized on the time information of the time-based clock external, so that the time drift of the time-based clock internal can be corrected.

Thus, when the power device is turned on, the clock based on of external time is updated by the information stored in the clock at internal time base.

This information of the clock based on internal time being kept up to date when the electrical equipment is energized by the information external time clock, this time information remains synchronize from one electrical device to another, so that when voltage of the electrical device, each electrical device displays and updates the external time-based clock from a common time information.

According to another preferred feature of the invention, the method of management includes a step of memorizing the time information of the time-based clock generated by the power supply network to at less a predetermined moment.

This memorization of the time of the clock based on external time allows, after a power failure of the device and its delivery voltage, to have access to a representative hourly information of one hour which the electrical apparatus was actually energized.

According to an advantageous characteristic of the invention, the method of management includes a step of calculating a power cutoff duration of the apparatus, this cut-off time being obtained by the difference between the time information stored in a time-based clock internal obtained at the reading step and the time information stored at the step memorisation.

It is thus possible to know the cut-off time of the power supply of a device, which is particularly interesting for appliances of the refrigerator or freezer type for which the duration of a cut off the power supply can jeopardize the conservation of food.

According to another embodiment of the invention, the information time clock based on internal time is set to zero at least one predetermined time.

This zeroing of the internal time clock makes it possible moment of powering up the device, to display a hourly information substantially corresponding to the duration of the break electrical appliance.

Preferably, this zeroing is performed during the detection de-energizing the electrical appliance.

After powering up the electrical appliance, the information time read in the clock based on internal time, updated in the clock at external time base and displayed actually corresponds to the duration of the switch off the power supply of the device.

• une horloge à base de temps interne ;
• une horloge à base de temps générée par le réseau d'alimentation électrique dudit appareil ;
• des moyens d'affichage d'une information horaire de l'horloge à base de temps générée par le réseau d'alimentation électrique ;
• des moyens de détection d'une mise sous tension dudit appareil électrique ;
• des moyens de lecture d'une information horaire mémorisée dans l'horloge à base de temps interne ; et
• des moyens de mise à jour de l'horloge à base de temps générée par le réseau d'alimentation électrique, par l'information horaire mémorisée dans l'horloge à base de temps interne.

According to a second aspect of the invention, an electrical apparatus adapted to implement the display management method according to the invention comprises:

• a clock based on internal time;
• a time-based clock generated by the power supply network of said apparatus;
• means for displaying a time information of the clock based on time generated by the power supply network;
• means for detecting a power-up of said electrical apparatus;
• means for reading a time information stored in the internal time clock; and
• means for updating the time-based clock generated by the power supply network, by the time information stored in the internal time-based clock.

This electrical appliance has features and benefits analogous to those of the method of managing an information display schedule that it is adapted to implement.

Other features and advantages of the invention will appear still in the description below.

• la figure 1 est un schéma bloc illustrant un appareil électrique conforme à l'invention ;
• la figure 2A illustre un montage électrique d'une horloge à base de temps externe ;
• la figure 2B est une courbe illustrant la synchronisation d'une horloge à base de temps générée par le réseau d'alimentation électrique de l'appareil ;
• les figures 3A, 3B et 3C sont des algorithmes illustrant le procédé de gestion conforme à un mode de réalisation de l'invention ; et
• les figures 4A et 4B sont des algorithmes illustrant le procédé de gestion conforme à un autre mode de réalisation de l'invention.

In the accompanying drawings, given as non-limiting examples:

• Figure 1 is a block diagram illustrating an electrical apparatus according to the invention;
• Fig. 2A illustrates an electrical mounting of an external time clock;
• Fig. 2B is a graph illustrating the timing of a time-based clock generated by the power supply network of the apparatus;
• FIGS. 3A, 3B and 3C are algorithms illustrating the management method according to an embodiment of the invention; and
• Figures 4A and 4B are algorithms illustrating the management method according to another embodiment of the invention.

We will first describe an electrical device adapted to put in implement the display management method according to the invention.

This electrical apparatus is illustrated schematically in FIG.

Only the functional elements of this device that allow the implementation of the hourly information management were illustrated, the whole elements and operating members specific to the electrical appliance not being represented.

This electrical appliance can be in particular a cooking oven domestic or even a microwave oven. It can also be constituted a refrigerator or freezer.

It has an internal time clock 10 and a clock external time base 20, generated by the power supply network 30 of the device 1.

The internal time-based clock 10 is a real-time clock or Real Time Clock (RTC). This clock RTC 10 includes means of incrementing one hour RTC 11, a quartz 12 and a system emergency power supply 13.

This emergency power supply 13 thus constitutes a system Stand-alone power supply of the RTC 10 clock.

In the embodiment illustrated in FIG. 1, this system Autonomous power supply consists of a battery.

Of course, this battery 13 could be replaced by a capacitor associated with a diode for charging the capacitor by the power supply to the device when it is powered on. The capacitor is then adapted to discharge when the electrical device is off to power the RTC clock. Such a system implementing a capacitor with a capacitance equal for example to 47 mF has a autonomy greater than 48 hours. The stack 13 and the incrementation means of the time RTC 11 associated with quartz 12 make up an autonomous system of time increment with quartz for time base.

The accuracy of such a clock RTC 10 is fixed by the quartz used, and in particular depends on the precision of quartz and its behavior in temperature.

The external time clock 20 is a synchronized clock on the electricity grid, and in particular by the zero crossing information of the mains voltage. This type of synchronization is commonly called sector synchronization.

This external time-based clock 20 includes a memory fast 21 (RAM or Ramdon Access Memory) adapted to memorize information hourly, also called in the following hour sector.

The increment of the time information of this clock based on external time is achieved at the level of a microcontroller 22 adapted to analyze the value of the voltage V delivered by the power supply 30 of the apparatus electric 1.

FIG. 2A illustrates for this purpose an electrical assembly allowing connect the microcontroller 22 to the phase of the power supply 30 of the device. In this embodiment, three resistors connected in series R have an impedance of 470 KΩ and the diodes D are of the type 1N41 48.

Of course, other methods for obtaining a synchronized signal on the power supply could be used, implementing by example a photo coupler, a transistor circuit or a detector of peak signal.

In order to ignore the disturbances of the power supply, and in particular not to count down the untimely zero crossings of the voltage, a timer associated with the microcontroller 22 is used.

FIG. 2B illustrates an example of obtaining this synchronization on the zero crossing of the voltage.

The upper part of the curve shows the voltage of the sector, and in particular the zero crossings of this voltage at the intersections of this curve with the line X.

The gray rectangles symbolize the duration of the timer which is slightly less than half a period of electrical voltage. During the duration of the timer, the zeroing of the voltage is ignored. So, although the microcontroller input detects multiple zero crossings of the voltage, some of these zero crossings are not taken into account that they take place during the duration of the timer, that is to say in a period of time predetermined after each valid zero crossing of the voltage. For that, to each valid zeroing of the voltage, the timer is reset.

Thus, at the input of microcontroller 22, information is obtained synchronized with the mains voltage. For example, for a network 50 Hz, by dividing this frequency by 100, we obtain a base of frequency of 1 Hz, that is, one variation per second.

The time information in memory 21 can thus be incremented to from this time base of 1 Hz, the time information being thus incremented every second.

Display means 23 make it possible to display information time, and in particular the display of the sector time in memory 21 synchronized to the power supply.

The electrical apparatus 1 also comprises means for storage 24 consisting for example of a non-volatile memory (of the type EEPROM) which is adapted to memorize the clock information of the clock based of time generated by the power supply network.

In practice, this information is addressed by the microcontroller 22 from the sector time in memory 21.

In order to allow the implementation of the time management method of the invention, the microcontroller 22 is associated with software means including means for reading the time information stored in the clock RTC 10, means for setting the information to zero time of the clock RTC 10 and means for calculating a cut-off time of the power supply from the time information stored in the non-volatile memory 24 and the clock RTC 10.

In addition, the software means of the microcontroller 22 are adapted to detect the powering up of the electrical device as well as possibly its shutdown.

This detection of tensioning of the apparatus can be carried out at from the zero crossing information of the voltage, power off being detected a contrario when no zero crossing of the voltage is detected for a predetermined duration.

They also include means for updating reciprocal of the clock information RTC 10 and information time of the external time-based clock 20.

Thus, the microcontroller 22 includes means for updating the the RTC time in memory 11 by the sector time in memory 21 and vice versa.

Of course, the schematic representation of FIG. limiting. In particular, the communication bus between the different elements can be different.

We will now describe with reference to FIGS. 3A to 3C a first embodiment of the method for managing an information display time according to the invention.

This method of managing a display of a time information can to be implemented in an apparatus as described above thanks to the use of an internal time clock and a clock based on external time 20.

As shown in Figure 3A, when the device is in normal operation, and after initialization of the clock RTC 10 and the external time-based clock 20, keeping on time the clock based external time is achieved through the synchronization of time on the frequency of the electricity network. As explained previously in reference in FIG. 2B, a timer is used at the microcontroller 22.

At each detection of a zero crossing of the value of the voltage, an E10 test step makes it possible to check whether the duration of the timer is over. In the negative, the process ends and the zeroing of the voltage is ignored. This is for example a zero crossing E as illustrated in Figure 2A which actually corresponds to a disturbance of the electrical signal.

On the other hand, if the test step E10 indicates that the duration of the timer is actually completed, the timer is reset in a reset step E11.

An increment step E12 is adapted to increment by one unit a state change counter of the voltage.

An E13 test step makes it possible to check whether this counter of state change has reached the value of 100.

If not, the process ends until a next detection of the zero crossing of the voltage.

When the state change counter has reached the value 100 to the outcome of the test step E13, an incrementing step E14 of the hour sector is implemented. In practice, the time sector is increased by value of one second.

Of course, the threshold value equal to 100 depends on the frequency of the power supply network and is valid in the case of a power supply electrical at the frequency of 50 Hz.

A reset step E15 of the state change counter is then implemented to reset this counter.

The set of steps E10 to E15 is then reiterated at each zeroing of the voltage, in order to maintain the synchronization of the time sector on the frequency of the electrical network.

In parallel with this synchronization, an update process is realized as shown in Figure 3B.

In this embodiment, this update is carried out at moment of detecting de-energizing of the electrical device.

This mode of operation is made possible in the case where the electrical apparatus has, after stopping, a power reserve, of the order 100 ms after power failure.

In such a case, after an E20 detection step of voltage of the electrical apparatus, an update step E21 of the information time of the RTC clock by time information of the clock based on time external is implemented.

In practice, this update step E21 consists of a operation of writing the sector time in memory 21 in the memory 11 of the clock RTC 10.

In this embodiment, a storage step E22 of the time information of the external time-based clock is also set implemented.

This storage step E22 consists of a writing step of the sector time in memory 21 in the non-volatile memory 24. The time stored in this non-volatile memory 24 is called in the following the description the memorized time.

Although this embodiment has been described as updating the the RTC time and the time stored in the non-volatile memory 24 during the detection of a power down of the electrical device, these steps of setting could also be implemented periodically when the electrical apparatus is undervoltage, and for example every minute.

In this case, the power off detection system of the device is no longer needed.

Thus, the RTC time is regularly updated from the hour sector, thus avoiding any drift of this hourly information, notably due to a temperature drift of the quartz.

We will now describe with reference to Figure 3C the implementation of the method for managing the display of a time information when the apparatus electrical power is turned on.

In practice, a detection step E30 is adapted to detect the energizing the electrical appliance.

This power-up can be performed after a break unintentional power supply or when connecting the electrical appliance by a user.

When the power is turned on, a step reading E31 is adapted to obtain the RTC time memorized in the memory 11 of the clock RTC 10.

Thanks to the update method described above with reference in Figure 3B and the standalone power supply of the internal time clock 10, the RTC time is the actual time.

An update step E32 of the clock based on time generated by the power supply network is implemented from the hour RTC read at reading step E31.

This update step E32 resets automatically the value of the clock 20 synchronized to the frequency of the electrical network from the time memorized in the RTC clock.

In practice, the value of the RTC time is copied to the memory 21 of the external time clock 20.

In this embodiment, a calculation step E33 makes it possible to calculate the cut-off time of the power supply of the appliance. In practical, this cut-off time is obtained by the difference between the time information stored in the RTC clock, as obtained at step reading E31, and the time information stored in the non-volatile memory 24 of the apparatus as stored in the storage step E22 described in reference to Figure 3B.

A display control can optionally be operated by the user to allow the temporary display at the level of the means display 23 of the apparatus of this cut-off time thus calculated by the micro-controller E22.

Finally, an E34 display step makes it possible to inform the user of the sector time updated from the time information obtained at the step of reading E31.

Thanks to this management method according to the invention, the information clock managed by the synchronized clock on the frequency of the electrical network can be permanently correct after a unique initialization of this hourly information at the time of commissioning of the electrical apparatus.

In addition, when several similar electrical appliances are used, the time information displayed by each of these devices remains synchronized in time.

In any case, the method may comprise a test step E35 to check whether the user wishes to make a setting of the external time-based clock.

This test step E35 can consist in detecting the actuation by the user of a particular command accessible on an array of control of the device.

If yes, the sector time in memory 21 is updated in a step E36 from a new value introduced by the user.

In such a case, an update step E37 is implemented in order to automatically update the RTC time in memory 11 from the modified sector time in update step E36.

Similarly, an update step E38 of the time stored in the non-volatile memory 24 is implemented from the hour sector acquired in the update step E36.

The whole process is then reiterated when a new E30 power up of the electrical device is detected.

Of course, in another embodiment of the invention, the non-volatile memory could be removed when it is not useful to obtain the cut-off time of the power supply.

In such a case, the update steps E22, E38 of the hour memorized and the calculation step E23 of the cut-off time are omitted.

We will now describe with reference to FIGS. 4A and 4B another embodiment of the invention.

This embodiment of the invention also uses the time synchronization sector as described above for reference in Figure 3A.

When the device is under voltage, an E40 detection step a power off of the device is implemented.

If so, the RTC time in memory 11 of the clock based on internal time is set to zero in a zeroing step E41.

Although this zeroing step E41 is preferably performed when detecting a power down of the electrical device, it could also be performed periodically, when the electrical device is under voltage, and in particular every minute. In this case, the means of Detection of the power off of the device can be removed.

The method of managing the time information at the device level electrical circuit comprises, as illustrated in FIG. 4B, a detection step E50 a power supply of the electrical apparatus.

As before, this power up of the device electrical can be performed after an untimely power failure electrical outlet or following a connection of the electrical appliance to the mains.

A reading step E51 of a time information stored in the clock RTC is then implemented.

Since the RTC time has been periodically reset when the electrical apparatus is under-voltage, or at least upon detection of a de-energizing, as previously described with reference to FIG. 4A, the RTC time in memory 11 obtained at this reading step E51 corresponds in reality to the duration of the cut of the electrical supply.

An update step E52 of the sector time is performed from the hourly information obtained at the reading step E51.

A display step E53 of the sector time thus makes it possible to display the duration of the power failure.

A test step E54 makes it possible to identify a possible setting of the time by the user as described above with reference to step E35 of Figure 3C.

If so, a step E55 update of the hour sector in memory 21 is implemented.

This embodiment of the invention thus makes it possible to obtain the duration power supply, without requiring the use of a non-volatile memory.

Knowledge of the duration of the power outage electric is particularly interesting for electrical appliances of the type refrigerator or freezer to detect a possible break in the chain of cold storage food stored in this type of device.

Of course, many changes can be made to the embodiments described above without departing from the scope of the invention.

Claims (18)

A method of managing a display of time information in an electrical apparatus (1) comprising an internal time clock (10) and a time-based clock (20) generated by the electrical power supply network apparatus, characterized in that it comprises the following steps: sensing (E30, E50) of energizing the electrical apparatus; reading (E31, E51) a time information stored in an internal time clock; updating (E32, E52) the time-based clock (20) generated by the power supply network with the time information stored in the internal time clock (10); and displaying (E34, E53) said time information of the time-based clock (20) generated by the power supply network. Management method according to claim 1, characterized in that the time information of the internal time clock (10) is updated at least one predetermined time by the time information of the clock (20). ) based on time generated by the power supply network. Management method according to claim 2, characterized in that said update is performed periodically when the electrical apparatus is powered. Management method according to claim 2, characterized in that said update is performed during the detection (E20) of a power off of the electrical apparatus. Management method according to one of Claims 1 to 4, characterized in that it furthermore comprises a step of storing (E22) the time information of the clock based on time generated by the supply network. at least a predetermined time. Management method according to claim 5, characterized in that said storing step (E22) is carried out periodically. Management method according to claim 5, characterized in that said storage step (E22) is implemented after detection (E20) of a power off of the electrical apparatus. Management method according to one of claims 5 to 7, characterized in that it further comprises a calculation step (E33) of a duration of cut-off of the power supply of the apparatus, said cut-off time being obtained by the difference between said time information stored in an internal time clock (E31) obtained in the reading step and said time information stored in said storing step (E22). Management method according to claim 1, characterized in that the time information of the internal time clock (10) is set to zero at at least a predetermined time. Management method according to claim 9, characterized in that said zeroing (E41) is performed periodically when the electrical apparatus is energized. Management method according to claim 9, characterized in that said zeroing (E41) is performed during the detection (E40) of a power off of the electrical apparatus. Electrical apparatus adapted to implement the display management method according to one of claims 1 to 11, characterized in that it comprises: an internal time clock (10); a time-based clock (20) generated by the power supply network (30) of said apparatus (1); means (23) for displaying a time information of the time-based clock (20) generated by the power supply network (30); detecting means (22) for energizing said electrical apparatus; reading means (22) for a time information stored in the internal time clock (10); and means (22) for updating the time-based clock (20) generated by the power supply network with the time information stored in the internal time clock (10). Electrical apparatus according to claim 12, characterized in that it further comprises means (22) for updating the clock information of the internal time clock (10) with the time information of the clock. time-based clock (20) generated by the power supply network (30). Electrical apparatus according to one of claims 12 or 13, characterized in that it comprises storage means (24) adapted to store at a predetermined time a time information of the time-based clock (20) generated by the power supply network. Electrical apparatus according to claim 14, characterized in that it comprises means (22) for calculating a cut-off time of the power supply. Electrical apparatus according to claim 12, characterized in that it comprises means (22) for zeroing the time information of the internal clock (10). Electrical apparatus according to one of claims 12 to 16, characterized in that said internal time clock (10) is a real time clock (11) associated with a quartz (12) and an autonomous power supply ( 13). Electrical apparatus according to one of claims 12 to 17, characterized in that the time-based clock (20) generated by the power supply network (30) of the apparatus is a clock synchronized with the frequency of the electrical network.

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