FR2728710A1 - Electronic card with function that can be activated manually - Google Patents

Abstract

The electronic card has a plastic body (1) enclosing the functional components (2) which are supplied from a battery (3). The battery is connected to a sensor (4) whose physical properties vary when it is subject to a manual operation. An electronic circuit (6) controls operation of the functional circuit in response to the state of the sensor. The sensor may be activated by the card having a speed in a set range, by a strain gauge responding to flexing of the card, or by a thermistor activated by heat from a finger placed on the card. This may be improved with two thermistors responding to temperature difference between the finger and ambient temperature. Thermocouples may be used in a similar way. Variation of impedance between two electrodes can also be used.

Description

Electronic card comprising a manually activated functional element "
The present invention relates to an electronic card comprising a plastic body containing a functional element powered by an energy source.

 The electronic cards dc cc type nc are not currently provided with actuation means making it possible to activate and / or deactivate their functional element. The thickness of the body of these cards is cn effect too small for one can install on them an intcrruptcur or a push button intended to control the activation of the functional element.

 The present invention proposes to remedy this shortcoming and. to do this, it relates to an electronic card of the type indicated above, which is characterized in that the source of energy is relicc to a sensitive element in which a physical quantity varies when subjected to manual action linear, and to an electronic circuit capable of supplying a control signal to the functional element in response to a signal emitted by the sensitive element and corresponding to a value of the physical quantity, situated in a range of predetermined values.

 The sensitive element used can be made with small dimensions, which allows it to be installed in the body of electronic cards. or even on one side of them, without protruding outside.

 As the functional element is only activated when necessary, the energy losses which have been relatively high up to now are avoided. The energy source can therefore be used much longer than current sources.

 It will also be noted that an untimely activation of the functional element is not possible since the electronic circuit nc can control the latter when the physical quantity rcstc is less than the minimum value of the activation range nor when this quantity becomes greater at the maximum value of said range.

 In order to limit the risks of inadvertent activation of the functional element, it is preferable for the electronic circuit to deliver the control signal only when the value of the physical quantity varies at a speed situated within a predetermined speed range.

 The functional element will therefore not be activated if the value of the physical quantity varies at a speed lower than the minimum X itcssc dc the speed range or greater than the maximum speed dc ccttc range.

 According to a prcmicr embodiment of the invention, the sensitive element is a strain gauge arranged in the plastic body while the physical quantity is an electric current whose intensity varies when the plastic body is subjected to manual bending in a zonc adjacent to the strain gauge.

 To prevent an involuntary flexion of the card body triggering an untimely activation of the functional element. a second strain gauge connected to the electronic circuit is ax antagcuscmcnt disposed in the plastic body, the electronic circuit providing the control signal to the functional element when the difference of the instantaneous values of the electric currents passing through the strain gauges is located in a range of values determines.

 According to a second embodiment. the sensitive element is a thermal resistance while the physical quantity is the electrical resistance of the thermal resistance, which varies when the latter is heated by a finger deliberately applied against it.

 In order to prevent heating of the thermal resistance by an external source, it triggers the activation of the functional element. a second thermal resistance is connected to the electronic circuit. this one providing the control signal to the functional element when the difference of the instantaneous values of the electrical resistances of the two thermal resistances is situated within a determined range of xcurs.

 According to a third embodiment. the sensitive element is a thermocouple while the physical quantity is an electromotive force whose magnitude varies when the thermocouple is heated by a finger voluntarily applied against it.

As an unintended heating of the thermocouple could trigger
activation of the functional element. it is desirable that a thermocouple sccond is connected to the electronic circuit. this one providing the command signal to the element
functional when the difference of the instantaneous nalcurs of the electromotive forces created in the two thermocouplers is located within a determined range of values.

It will be specified here that the sensitive elements used in the three modes of
above embodiment are embedded in the body of the electronic cards, but could be in the plane of one of the large faces of the body of the latter.

 According to a fourth embodiment, the sensitive element consists of two adjacent electrodes arranged on the body of plastic material while the physical magnitude is the impedance established between the two electrodes and varying when a finger is deliberately applied against said electrodes .

 To prevent an external organ causing an untimely variation of the impedance and triggering the activation of the functional element, two other adjacent electrodes connected to the electronic circuit are placed on the plastic body, the electronic circuit providing the signal dc control to the functional element when the impedances respectively established between the paired electrodes are the same and vary at the same speed.

Several embodiments of the present invention are described below by way of non-limiting examples with reference to the accompanying drawings in which
- Figure 1 is a schematic perspective view of an electronic card according to the invention
FIG. 2 is a diagram of an electronic circuit capable of being inserted in the body of the card visible in FIG. 1. ct
- Figures 3 to 5 are schematic views of other electronic cards according to the invention.

 The electronic card which can be seen in FIG. 1 comprises a flat body 1 made of plastic. having two large opposite rectangular faces, the thickness of which is less than 1 mm.

 Its body 1 contains a functional element 2 constituted for example by a microcircuit or a chip. an energy source 3 such as an electric battery, two strain gauges 4.5 located at two locations distant from each other, and an electronic circuit 6.

 Conductive links 7, 8, 9 are provided for electrically connecting the electronic circuit 6 to the strain gauges 4 and 5 and to the functional element 2. Other conductive links 12.13 are for their part provided for electrically connecting the source of energy 3 to the electronic circuit 6 and to the functional element 2.

 The electronic circuit 6 is produced so as to allow the circulation of electric currents in the strain gauges 4 ct 5 when the parts of the body 1 which are adjacent to the latter are subjected to manual bending, and to supply the functional element 2 a control signal when the difffrcncc of the instantaneous values of the electric currents in the gauges is situated within a predetermined range of values.

Thus, when the parts of the body 1 which are adjacent to the strain gauges are subjected to flexions of the same order of magnitude. and that the value of the aforementioned difference remains less than the minimum value of the predetermined range,
The functional element 2 nc will not be activated by the electronic circuit 6.

 We can meet such a situation. for example when an electronic card kept in a pocket of a user's clothing is involuntarily subjected to weak local bending over its entire surface.

 Similarly, if the parts of the body 1 which are adjacent to the strain gauges are subjected to different flexions to the point that the value of the above-mentioned difference becomes greater than the maximum value of the predetermined range, the functional element 2 will not always be not activated by the electronic circuit.

 Such a situation can for example be encountered when the body of the electronic card is accidentally subjected to strong bending in the vicinity of a single strain gauge.

 In the embodiment which comes from being described. the body of the card has two strain gauges. It goes without saying that it would not go beyond the scope of the present invention if there were only one.

 In that case. the electronic circuit 6 could be made dc such that the functional element 2 is only active if the electric current flowing in the gauge has an intensity situated within a predetermined range of values. and that untimely activation of the functional element is avoided.

 In order to reduce the risks of unintentional activation, the electronic circuit 6 could also be designed so that the functional element is only activated if the value of the intensity of the current flowing in the strain gauge varies to a speed located in a predetermined speed range.

 An exemplary embodiment of the electronic circuit 6 thus designed is shown diagrammatically in FIG. 2.

As can be seen from this figure, circuit 6 has a bridge
Wheatstone P, one branch of which is formed by the strain gauge (4 or 5) and two opposite vertices of which are connected to the positive and negative trunks of the energy source, a differential analog amplifier circuit 14 connects to the two other opposite vertices of the Bridge from Wheatstonc and powered by the energy source. and two circuits 15, 16 mounted in parallel between the amplifier circuit 14 and the functional element 2, the circuit 15 making it possible to measure the variation dc of the intensity of the current flowing in the gauge while the circuit 16 makes it possible to measure the itcssc to which varies the intensity of this current.

 The electronic card shown in Figure 3 differs slightly from that which has been described with reference to Figure l. Instead of comprising two strain gauges, it in fact comprises two thermal resistors 4a, 5a whose electrical resistances vary when they are heated.

 Otherwise. its electronic circuit 6a is designed to activate the functional element 2 when the difference of the instantaneous values of the electrical resistances of the thermal resistors 4a.5a is situated within a range of predetermined values.

 So. when the user applies a finger to the part of the body 1 which is adjacent to a thermal resistance. one heats up while the other stays at room temperature.

 The electrical resistance of the thermal resistance which is heated varies from that of the other thermal resistance. so that the difference between the instantaneous values of the electrical resistances takes an alcure for which the electrical circuit 6a activates the functional element 2.

 On the other hand. if the user places a card in a homogeneous cold or hot atmosphere, the difference between the instantaneous alcurs of the electrical resistances will be practically nullc and the functional element l nc will not be activated.

If now the temperature of one of the body parts 1 which is adjacent to a thermal resistance undergoes a significant variation, and if the difference between the instantaneous values of the electrical resistances of the two thermal resistances is greater than the maximum value of the predetermined range of values. functional element 2 will still not be activated
The electronic card shown in Figure 3 could have only one thermal resistance.

 In this case, the electronic circuit 6a could be produced so that the functional element 2 is only activated if the user. cn applying a finger to the part of the body 1 which is adjacent to the thermal resistance. causes the electrical resistance of the latter to take an alkur situated in a predetermined range of values.

 In order to reduce the risks of inadvertent activation of the functional element 2, the electronic circuit ôa could also be designed so that the latter is only activated if the "resistance of the thermal resistance varies at a speed located within a predetermined speed range.

 The electronic card represented in FIG. 4 differs from the cards described above in that the strain gauges and the thermal resistances have been replaced by two thermocouples 4b.5b.

 Its electronic circuit () b is itself designed to activate the functional element 2 when the difference between the instantaneous values of the electromotive forces created in the two thermocouples is located within a predetermined range of values.

When the user applies a finger to the part of the body 1 which is adjacent to a thermocouple. this one heats up while the other thermocouple stays at room temperature
The electromotive force of the thermocouple which is heated varies compared to that of the other thermocouple dc such that the difference between the instantaneous values of the electromotive forces takes a value for which the electronic circuit 6b activates
functional element 2.

On the other hand. if the user places a card in a homogeneous cold or hot atmosphere the difference between the instantaneous values of the electromotive forces will be practically zero and the functional element 2 will not be activated
If now the temperature of one of the body parts 1 which is adjacent to a
thermocouple undergoes a significant variation, ct if the difference between the values
of the electromotive forces of the two thermocouplers is greater than the value
maximum of the predetermined range of values. functional element 2 will not always
not activated.

 The electronic card shown in Figure 4 could have only one thermocouple.

 In that case. the electronic circuit () b could be made dc so that the functional element 2 is only activated if the user, by applying a finger to the part of the body 1 which is adjacent to the thermocouple. made to take the electromotive force of it. a value within a predetermined range of values.

 In order to further reduce the risks of an involuntary activation of the functional element 2. the electronic circuit () 11 could also be designed so as to activate the latter only if the value of the elromed force dries up at a speed situated in a predetermined speed range.

 In the three embodiments which have been described above, the strain gauges, the thermal resistors and the thermocouples are embedded in the body of the electronic cards. It goes without saying, however, that they could be located in the plane of one of the large faces of said cards.

 The electronic card represented in FIG. 5 differs from the cards described above in that it comprises two adjacent electrodes 4c.5e on each of its large faces, the two pairs of electrodes replacing the strain gauges as well as the thermal resistances and the thermocouples.

 Its electronic circuit 6e is itself designed to activate the functional element 2 when the user. by applying a finger to each pair of electrodes, allows the establishment of impedances of the same value and varying at the same speed.

 This solution has in fact been adopted in order to prevent an involuntary phenomenon of eletroostrietion causing static electricity to appear and causing untimely activation of the functional element.

 It will be noted that the electrodes located on one of the large faces of the card are opposite the electrodes situated on the other face of the latter for obvious ergonomic reasons.

 The electronic card shown in FIG. 5 could have only one pair of electrodes on one of the large faces.

 In this case, the electronic circuit could be made dc so that the functional element 2 is only activated if the user. cn applying a finger to the two electrodes, varies the impedance at a speed within a predetermined speed range.

 Note also that it is desirable to shield the electronic circuit 6c and the other circuits associated with it in order to avoid the formation of electrostatic discharges.

 To be complete. it will be noted that the electn) niqucs cards according to the invention comprise a body made from two plastic plates fixed against each other by gluing or any other equivalent technique. the functional element 2, the energy source 3, and the electronic circuit 6 being located between these two plates just like the strain gauges 4.5, the thermal resistors 4a, 5a or the thermocouples 4b.5b.

 Finally, it will be noted that the present invention also covers an electronic card, the body of which would be provided with a combination of at least two different sensitive elements chosen from those described above.

Claims (10)

SALES  1. Electronic card comprising a plastic cn body (1) containing a functional element (2) supplied by an energy source (3). characterized in that the energy source is connected to a sensitive element (4,4a, 4b, 4c) in which a physical quantity varies when it is subjected to a manual manual action, and to an electronic circuit (6,6a , 6b, 6c) capable of providing a control signal to the functional element in response to a signal emitted by the sensitive element ct corresponding to a value of the physical quantity, located within a predetermined range of values.  2. Electronic card according to claim 1. characterized in that the electronic circuit (6,6a, 6b, 6c) only delivers the control signal when the value of the physical quantity varies at a speed situated in a range of predetermined speeds .  3. Electronic card according to claim 1 or 2. characterized in that the sensitive element is a strain gauge (4) disposed in the plastic body (1) while the physical quantity is an electric current whose intensity varies when the plastic body is subjected to manual bending in an area adjacent to the strain gauge.  4. Electronic card according to claim 3. characterized in that a second strain gauge (5) connected to the electronic circuit is disposed in the plastic body (1). the electronic circuit (6) supplying the control signal to the functional element (2) when the difference of the instantaneous values of the electric currents passing through the strain gauges (4.5) is situated within a predetermined range of values.  5. Electronic card according to claim I or 2, characterized in that the sensitive element is a thermal resistance (4a) while the physical quantity is the electrical resistance dc the thermal resistance. which varies when it is heated by a finger applied deliberately against it.  6. Electronic card according to claim 5. characterized in that a second thermal resistance (5a) is connected to the electronic circuit (6a). cclui this providing the control signal to the functional element (2) when the difference of the instantaneous values of the electrical resistances of the two thermal resistors is located within a determined range of values.  7. Electronic card according to claim 1 or 2. characterized in that the sensitive element is a thermocouple (Al) while the physical magnitude is an electromotive force whose magnitude varies when the thermocouple is heated by a finger voluntarily applied against it .  8. Electronic card according to claim 7 characterized in that a second thermocouple (5b) is connected to the electronic circuit (6b), the latter providing the control signal to the functional element (2) when the difference in instantaneous values electromotive forces created in the two thermocouples (4a, 5b) is within a predetermined range of values  9.Electronic card according to claim 1 or 2. characterized in that the sensitive element consists of two adjacent electrodes (Ac) arranged on the plastic body (1) while the physical quantity is impedance established between the two electrodes and varying when a finger is applied 'olontairemcnt against said electrodes.  10. Electronic card according to claim 9. characterized in that two other adjacent electrodes (5c) connected to the electronic circuit (6c) are arranged on the plastic body (1). the electronic circuit providing the control signal to the functional element (2) when the impedances respectively established between the paired electrodes (4c.5c) are the same and vary at the same speed.