FR2923096A1 - Rechargeable cell housing and autonomous electronic system associating device for e.g. autonomous electrocardiogram recorder, has trap taking closed-starting position to drive change of switch state to control exit point of consumption mode - Google Patents

Abstract

The device has a plug type cell trap (14) charged to close a cell compartment (7) and taking a closed-starting position to drive a change of state of a mechanical magnetic on-off switch (9) connected to an entry line of a microcontroller (12) so as to indicate a passage and taking-off of the position at the microcontroller. The change of state of the switch controls the microcontroller passage in a low consumption mode when the trap takes off the position, and controls an exit point i.e. starting of an application such as data storage, of the mode when the trap positions on the position.

Description

The invention consists of a device for making reliable and simplify the devices operating with battery (s) or interchangeable rechargeable elements and using a microcontroller. For the sake of clarity, the term battery will be used in the text whether it is a single battery, multiple batteries or rechargeable element (s). These devices must indeed face the risk of being brutally deprived of their energy source when the user removes the battery. This removal exposes the microcontroller to lose data in memory as soon as its supply voltage drops below a certain threshold, which may be incompatible with the application: time, date, settings preserved, identification, data storage. .. can not be lost without prejudice to the user. It is of course possible to detect the drop in the power supply voltage and abruptly interrupt the program flow in order to force the microcontroller to go into very low power mode, which is not a problem on current applications, except when performing complex and relatively long tasks such as launching a data transfer to a mass memory: it can not then immediately interrupt the operation of the processor without the risk of introducing major errors in the mass memory. Manufacturers generally solve this problem by placing a battery or backup battery (3) of sufficient size on the power supply (2) to provide the energy needed to close complex tasks (Figure 1): When the voltage of the main battery (1) falls below a defined threshold, the power supply circuit (2) connects to the backup battery (3) in order to maintain its output line (4) which supplies the processor (5) and its peripherals (6) at a sufficient voltage. This method has two disadvantages: to have a component whose size and cost come to burden the volume and the price of the device, and especially as the energy required is high, manage the charge of a battery under variable operating and temperature conditions, and integrating a component whose service life is generally shorter than that of other components, which will inevitably result in failures in the longer term. Another proposed solution is not to allow access to the rechargeable element present in the device and providing energy. But the impossibility of maintaining the part that is generally the most sensitive to aging is only suitable for short-lived appliances. The battery trap (s) with 3 successive stable positions: The invention consists of a device (FIG. 2) associating at least one battery compartment (7) and a microcontroller (12), in which the element (14) charged to close the battery compartment, called battery door, can take three successive stable positions: an open position giving access to the battery compartment, a closed-off position closing this compartment, and a closed-on position also closing the battery compartment , but causing the change of state of a switch (9) connected to an input line of the microcontroller (12) in order to signal to it the passage to this position or, conversely, the fact that it leaves this position. This element thus imposes the passage through the intermediate closed-off position that comes from the open position and that we want to start the device, or that we want to change the battery in the battery compartment. while the camera is on the road. Figures 3a, 3b and 3c describe the 3 stable positions of the hatch and the action on the switch. In 3a, the hatch is removed and the switch (9) open. In 3b, the hatch closes the battery compartment but leaves the switch open. In 3c, the hatch holds the compartment of the battery compartment and closes the switch (9). The last two positions are stabilized thanks to an element (Figure 2,16) pushed by a spring any other elastic means, which engages in recesses (15) present on the hatch. It is of course possible to provide other locking means in these stable positions, such as an elastic pin attached to the trap blocking in recesses in the housing of the device.

In the case of critical applications, in which the position change is to be carried out only by qualified persons, it prevents the passage from the closed-running position to the closed-off position if one does not have a tool. This functionality can be established by arranging on the exposed face of the battery door not a relief giving a finger grip, but a relatively narrow recess (20, FIG. 3a) or any adapted shape which makes it possible to exert with a tool a sufficient force to change position. It is also possible to place a lock that locks the hatch in the closed-running position and that requires the use of a tool for unlocking. An advantage provided by the invention is thus to integrate the stop-start button usually used in this type of application in the closing device of the hatch. It is therefore possible to economize this switch. A position indicator, formed for example by an arrow, facilitates the user's understanding of the system: this arrow points to an indication such as OFF or a symbol indicating that it is in the closed-off position or an indication such as ON or a symbol to indicate that one is on the closed-walking position. 3 Insofar as the battery present in the battery compartment serves to feed the microcontroller either directly or through the use of a regulator or a switching power supply (10) in order to obtain a voltage compatible with that microcontroller, it avoids any possibility of removing the battery while the device is operating in normal mode and put it in a perilous situation due to the sudden drop in power. To handle these different situations correctly, the microcontroller uses the information provided by the above-mentioned switch to stop most of its peripherals (13) and to go into very low power mode when it detects the closed-off position or the open position, and conversely, turn on the peripherals to run the application it is loaded when it detects the closed-walking position. This very low power mode generally consists, after saving the current data, to let only a clock operate to manage the time and date. This gives a very low power supply current, some microamperes in general, when it is necessary to remove the batteries. Under these conditions, the microcontroller can withstand the interruption of power caused by a change of the battery through the use of a power reserve of reduced size as simple capacitors able to maintain a suitable supply voltage during a minimum duration of a few tens of seconds. Indeed, the low current required to power the microcontroller in very low power mode imposes only ordinary capacitors and / or supercapacitors if one wishes to extend the backup time to several hours. Take for example a set that consumes globally 10 A in very low power mode and which has a simple capacitor of 10001, tF connected to the power supply line of the microcontroller, it must be maintained between 3.3V and 2, 0V. The 10 A current discharges the capacitor at: dV / s = 10.10-6 / (1000 x 10-6) = 10mV / s. Since the possible voltage difference is 3.3V ± 2.0V = 1.3V, and the capacitor is initially charged at 3.3V, the range is therefore: 1.3 / 10.sup.-3 = 130s. This time is more than enough to change a stack (s). However, it is desirable to have a higher time by placing for example capacitors of greater value (0.01 to 1.0F) but remaining small in the extent that the application is compact, such as supercapacitors. With a supercapacitor of 0.1F and under the same conditions as above, the autonomy is increased to 13,000s, more than 3 hours. The user can assimilate the very low consumption mode to a state of complete shutdown of the device. Operation: The time spent in very low power mode can take, without major risk, a few tens of milliseconds, which is very comfortable for most applications on microcontroller. The mechanical movement to move from the closed-running position to the closed-off position and then to the open position takes indeed at least a few hundred milliseconds, and it is necessary to add the time, still higher, to remove the batteries, which guarantees a large margin of maneuver. Figure 4 describes the different operating phases of the device: -In (24), the hatch is actuated and moves from the position (21) closed-off (OFF) to the closed-on position (ON. 22) detects this change by closing and the microcontroller (23) starts its applicati - En (25), the hatch is opened for a battery change.As soon as the hatch leaves the closed-on (ON) position, The switch (22) opens and the microcontroller (23) triggers its switch to low power mode, starting with data backup for a few tens of milliseconds (29) - In (26), the user makes the change - In (27), it puts the hatch and the place in the closed-on position, which restarts the application 25. In (28) it stops the apparatus by putting the hatch on the closed position Additional devices: For the autonomous device to be well secured, it must monitor the voltage Two methods of monitoring are found, one corresponding to the detection of a sudden drop in the battery voltage, possibly caused by a bad contact, the other making it possible to follow the progressive discharge of the battery. it. In the first case, the voltage of the stack (s) is compared with a threshold of minimum operating voltage, the output signal of the comparator feeding a microcontroller interrupt line responsible for making it go into very low power mode when the voltage of the battery goes below the aforesaid threshold. This ensures a classic case of urgency, which can happen when a battery contact is defective or a major shock causes a transient movement of the battery in its housing which interrupts the contact with one of the terminals. In the second case, the battery voltage is measured periodically by the microcontroller using an analog-digital converter, in order to monitor its voltage and detect a value below which it commands its switch to very low power mode. We then obtain a perfectly managed shutdown of the application because the microcontroller has a comfortable margin of maneuver if the value of the voltage threshold is chosen.

Shape of the hatch: The invention can be applied to different forms of traps. The most common are circular displacement cap traps or linear displacement slides. One can of course imagine displacements combining circular and linear or several linear of different axes.

The slide-type hatch has been described with reference (FIGS. 3a, 3b and 3c). It is of course possible to create all kinds of variants in which the switch (17) is placed either at the end or along a lateral edge on which an ergo comes to change its state. So that, in the closed-off and closed-on positions, the hatch perfectly conceals the battery compartment, the latter preferably has two plates in front of which slides the slide at its two ends: the upper plate (18) is visible in closed-off position (Figure 3b), the lower plate (19) is visible in the closed-on position (Figure 3c). The plug-type hatch (FIG. 5, 30) has a circular shape and closes the compartment containing the stack (32) by a bayonet or helical movement and preferably has a relief (31) directly or indirectly in contact with the the switch. The closed-off and closed-on positions are preferably stabilized by elastic elements integrated or not to the plug. In this case, the elastic element may be the spring used to lock the battery (generally at the - pole), and the shape of the mechanical elements ensures the stability of these two positions. The cap may also have a strap to avoid losing it in the open position. To avoid opening the device without tools, the plug has at least one slot in which it is possible to introduce a tool for rotating it. The switch: The device is described by having a mechanical switch that perfectly meets the need for position detection. Many switches exist in a variety of forms, and miniature models are ideally suited to a small application. Their control can be done by direct action of the hatch on their control lever, or by indirect action, that is to say by transmitting the movement of the hatch through one or more mechanical parts. It is of course possible to provide all kinds of mechanical switches, magnetic, capacitive, optical .. able to detect the movement of the battery door. The magnetic uses for example a magnet placed in the hatch and a field detector such as a Flexible Bladed Switch (ILS) or a Hall effect sensor sensitive to its magnetic field. Optics is not easy to adapt to a standalone application because it requires a transmitting diode that must be powered, which irreparably represents a reduction in autonomy. This diode is placed opposite a receiving diode so that a portion of the hatch obstructs the passage of light or triggers a reflection in the closed-walking position. However, this technique can be adapted by making a pulse measurement by sending only short pulses to the diode, the time to measure the existence or absence of an obstacle, which can significantly reduce consumption. Applications: Any application running on battery or battery and using a microcontroller can take advantage of such a device, especially if the application performs complex tasks such as data recordings on mass memories, very sensitive to power interruptions. Special mention is made of stand-alone long-term data loggers such as electrocardiogram recorders or other physiological signals.25 Description of the figures: Figure 1 depicts an autonomous system on a battery using a backup battery:

Figure 2 depicts the device with its battery compartment and the hatch controlling the switch connected to the microcontroller.

Figure 3 describes the 3 positions of the hatch and its effect on the switch.

Figure 4 describes the microcontroller mode of operation changes as a function of the position of the battery door.

Figure 5 depicts a cap type battery door 15

Claims (10)

1 / Device associating a battery compartment (7) or rechargeable elements and an electronic system with microcontroller (12) powered by the aforesaid batteries, characterized in that the hatch (14) responsible for closing the battery compartment (s) ), can take three successive stable positions, an open position giving access to the battery compartment, a closed-off position blocking access to the battery (s), and a closed-on position also blocking access to the battery (s) , but causing the change of state of a switch (9) connected to an input line of the microcontroller to signal to it the passage to this position or, conversely, the fact that it leaves this position, this change of state controlling the passage in very low power mode of the microcontroller when the hatch leaves the closed-running position, and controlling the output of this mode, that is to say the start of the application, when the trap is posi on the closed-walking position. 2 / Apparatus according to claim 1, wherein the microcontroller can withstand the power interruption caused by a change of the battery (s) through the use of capacitors (11) of sufficient size to maintain a voltage d suitable feeding for a minimum of a few tens of seconds. 3 / Apparatus according to one of the preceding claims, wherein during operation of the application, the voltage of the stack (s) is compared to a threshold of minimum operating voltage, the output signal of the comparator feeding a interrupt line of the microcontroller responsible for switching it to low power mode when the battery voltage falls below the aforementioned threshold. 4 / Apparatus according to one of the preceding claims, wherein the battery voltage is measured periodically by the microcontroller using an analog-digital converter, to monitor its voltage and detect a value below which it controls its switch to low consumption mode. 5 / Apparatus according to one of the preceding claims, wherein the hatch responsible for closing the compartment of the stack (s) is of the slide type can take the open position when removed, closed-off when it is partially depressed, and in the closed-walking position when fully depressed, at least a portion of which comes directly or indirectly in abutment on the aforesaid switch in order to change its state, the last two positions being stabilized by elastic elements integrated or not to the slide. 6 / Apparatus according to one of claims 1 to 4, wherein the hatch responsible for closing the compartment of the battery (s) is of cap type (30), has a circular shape and closes the compartment containing the battery ( 32) by a bayonet or helical movement, and preferably has a relief (31) coming directly or indirectly in contact with the switch, the closed-off and closed-on positions being preferentially stabilized by integrated elastic elements or no in the cap, elastic element may be in the latter case the spring used to block the battery, combined with the shape of the mechanical elements. 7 / Apparatus according to one of the preceding claims, wherein the switch (9) is mechanical, a portion of the trap being leaning directly or indirectly on the triggering element of the switch (fig.3c). 8 / Apparatus according to one of claims 1 to 6, wherein the switch is magnetic, using a magnet secured to the door and a magnetic field sensor 15 as a flexible blade switch or a specific component. 9 / Apparatus according to one of the preceding claims, wherein the battery door has on its exposed face a recessed shape (20 and 33) for actuating it with a tool to move from the closed position -marche at the closed-off position. 10 / Apparatus according to one of the preceding claims, applying to a recorder 20 autonomous electrocardiogram and electrophysiological signals.