FR2779551A1 - Mains current failure detection and warning circuit - Google Patents

Abstract

The circuit has different time delays imposed according to the cause of the current failure. The detection and alarm circuit is connected to the mains network by a standard plug fitted with an earth connection. It includes a circuit for detecting the absence of current and for detecting the operation of a circuit breaker. The circuit includes transistors (T3, T8) and a capacitor (C1) for determining two different time delays after which a warning is produced as a function of either the loss of supply current, or the activation of the circuit breaker. A short delay is used in the event of circuit breaker operation, and a longer delay in the event of supply failure. The current loss detection circuit includes a transistor (T2) which is in its blocked state in the presence of current, and its conducting state in the absence of current.

Description

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  Detection and alert system The present invention relates to a detection and alert system, used, for example in a detached house to detect in particular the

  power cuts, gas and / or water leaks, or any other event.

  It is known from French patent application 2551280, a detection and alert device for building surveillance. This device requires a telephone line and allows via this telephone line and sensors such as water leakage, gas and intrusion sensors, to alert a remote monitoring station. This device does not allow

  detection of a power cut.

  It is also known from French patent application 2637434, a telephone alarm device to alert the user in the event of a power outage or a drop in temperature in a refrigerating appliance. This device is based on a periodic detection of current and temperature present. In the event of an abnormal condition (more current or temperature below a determined threshold), the device alerts the user by taking a telephone line and automatically dialing a predetermined number. Detection takes place every ten minutes. As long as the conditions remain abnormal the telephone alert will take place systematically, as soon as the conditions are normal, there is no more alert. This device does not

  not differentiate a mains power cut from a circuit breaker.

  It is also known from French patent application 2652222, a device for remote monitoring of the electrical supply of an appliance. This device imperatively requires the presence of a telephone line. Indeed, the principle of the device is to make the telephone line occupied during a power cut. So when the user wants to check if the device is still on, they just have to call the telephone line. If the device is powered, the telephone line will ring "free", otherwise it will ring "busy", indicating to the user that there is no power supply. This device presents

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  the disadvantage of monopolizing a telephone line and not differentiating

  a mains power cut, a circuit breaker.

  The object of the present invention is therefore to overcome the drawbacks of the prior art by proposing a detection and alert system which is simple to set up and which makes it possible to differentiate a mains power cut, a circuit breaker and to provide different alert systems depending on the

type of cut.

  This object is achieved by the fact that the system is connected to the electricity distribution network by a standardized electrical outlet having a 1o connection to earth, that it comprises a circuit for detecting the absence of current comprising a circuit for disjunction test, this disjunction test circuit being connected to means for determining a different delay after which alert means are triggered as a function of the detection of absence of current and / or of disjunction, the alert means being triggered at short notice in the case of a lack of current detection with tripping and at a long time in the case of a lack of current detection

without disjunction.

  According to another particularity, the circuit for detecting the absence of current comprises a transistor which is in the off state during the presence of current and in the on state during a power supply failure, the on state of the

  transistor activating the circuit breaker test and a timing circuit.

  According to another particular feature, the timing circuit comprises a transistor, a capacitor and a plurality of resistors, the characteristics of the capacitor and of the plurality of resistors being determined as a function of the timing delay chosen by the user for triggering the means of alert when a lack of current is detected without tripping, the

  delay being between one and four hours.

  According to another particularity, the circuit for testing disjunction comprises a relay activated by the transistor of the circuit for detecting no current, activation of the relay makes it possible to check the continuity between the earth and the neutral of the circuit of the electrical outlet. , via a second transistor, which

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  turns on to activate the relay again in the event of continuity and which remains blocked to leave in the state the relay, if not, the blocked state of this second transistor decreasing the delay of the timing circuit, via the transition to the on state of a third transistor connected to the second transistor of the timing circuit. According to another particular feature, the alert means are triggered by a first relay activated by a transistor, which remains in the off state for a determined period, the first relay remaining activated, as long as there is no power supply and / or by a second relay activated by the same 1o transistor, which remains in the off state for a determined period, the second relay remaining activated for a period chosen by the user, the period after which the first and / or the second relay are activated is determined by the

timing circuit.

  In another feature, the system includes a circuit

  verification of connection to the electrical outlet.

  According to another particular feature, the connection verification circuit comprises a two-position switch, mounted on the phase, which, in a first position puts the system into service, and in a second position turns the system off and connects to a neon lamp mounted on the ground, this neon lamp testifying when it is on, on the one hand that the system is out of service, and on the other hand that the socket on which the

  system, is correctly connected to the electrical distribution network.

  According to another particular feature, the system comprises means for detecting water leakage and / or gas leakage, these means comprising an electric circuit open in normal condition and closed when detecting a water leakage and / or gas, closing this circuit activating the first and / or the

  second relay of alert means.

  According to another particular feature, the alert means comprise a telephone call device and / or an audible alarm and / or an indicator

luminous.

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  According to another particular feature, the water leak detection device comprises a probe creating a conductance in the presence of water, a first transistor connected to the probe and to a second transistor, the first transistor being in the off state in l absence of conductance on the probe and in the on state otherwise, the second transistor being in the on state when the first transistor is on, the on state of the second transistor causing the closure of the circuit activating the first and / or the second relay

means of alert.

  Other features and advantages of the present invention

  will appear more clearly on reading the description below made in

  reference to the accompanying drawing in which: - Figure 1 shows an electrical diagram of the system

monitoring according to the invention.

  - Figures 2 and 3 show an electrical diagram of two

  alternative embodiments of a water leak detection device.

  The system according to the invention is connected to the 220 V sector by a male plug in a standardized electrical outlet necessarily having an earth connection. The system is mainly intended for the detection of the presence of electric current, it is therefore necessary that the system can operate without electric supply from the distribution network. The system therefore comprises a rechargeable accumulator (40), connected, on the one hand to a rectifier bridge (41) connected to phase P and to the neutral N of the mains supply, and on the other hand to a capacitor (C5) connected between the positive and negative poles of the rectifier bridge (41). Two capacitors (C2, C3) connected on the one hand to the rectifier bridge and respectively, to phase P and to neutral N of the mains supply, ensure the current limitation and the voltage drop necessary to charge the accumulator (40). An LED indicator light (L1), connected on the one hand to the negative pole of the accumulator and by a Zener diode to the positive pole of the accumulator (40), indicates, when it is on, that the system is powered on. Advantageously, and for security reasons, the system includes a connection verification circuit. This circuit

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  comprises a two-position switch (51), connected to phase P of the system, upstream of the capacitor (C2) also connected to phase P and

  limiting the current, and a neon lamp (50) connected to the ground T of the system.

  In a first position, called closed, the switch (51) energizes the system according to the invention. In a second position, called open, the switch turns off the system and connects the phase P to the neon lamp (50) and to earth T. Thus, since the switch (51) is connected to the phase and the lamp ( 50) to earth, the lamp (50) should light up if the standard electrical outlet to which the system is connected is correctly mounted, i.e. if the phases, the neutral and the earth, respectively of the system and the socket correspond. In the case where the electrical outlet is not mounted correctly, the earth and the phase of the system plug do not correspond to the earth and the phase of the mains socket, the

  neon lamp (50) does not light up.

  The system comprises a circuit for detecting the absence of current, this circuit comprises a first transistor (T2) and a diode (D1l) whose cathode is connected to the positive terminal of the accumulator (40) so that the diode ( D1) is blocked as soon as there is no more current on the sector then allowing the transistor (T2), the base of which is connected to the negative pole of the accumulator (40) by a resistor (R1), to become passerby. The change of state of the transistor (T2) triggers, on the one hand a time delay circuit, and on the other hand, a circuit for testing disjunction. The timing circuit includes a second transistor (T3), for example with low energy consumption, a capacitor (C1) and three resistors, two of which are fixed (R2, R3) and one variable (R4). The

  second transistor (T3) is connected by the emitter to the variable resistor (R4) itself

  even connected to the negative pole of the accumulator. The base of the second transistor (T3) is connected to the collector of the first transistor (T2) by a first fixed resistor (R3), connected in series with a capacitor (C1l) and the cathode

  a diode (D2) whose anode is connected to the collector of the first transistor (T2).

  The point common to the first fixed resistor (R3) and to the capacitor (C1) is connected to the cathode of a diode (D6) whose anode is connected, on the one hand to the

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  ground, and on the other hand to the second fixed resistor (R2) whose other terminal is connected to the common to the capacitor (C1) and to the diode (D2). Thus, when the first transistor (T2) of the absence of current detection circuit is conducting, the second transistor (T3) of the timing circuit also becomes conducting depending on the values of the capacitor (C1l) and the three resistors (R2, R3, R4), thus creating a time delay. Advantageously, the values of the capacitor (C1l) and of the three resistors (R2, R3, R4) are determined to create a time delay between one and four hours. The second transistor (T3) of the timing circuit is connected to a first amplification circuit comprising a first (T4) and a second transistor (T5), the emitter of which is connected, on the one hand to ground through a resistor (R5), and on the other hand to the anode of a first diode (D4). The cathode of this diode (D4) is connected, on the one hand to the ground through a resistor (R8) and to the cathode of a second diode (D8). Thus, the first transistor (T4) of the first amplification circuit ensures current voltage transfer and the second transistor (T5) operates as a current preamplifier ensuring blocking, via the two diodes (D4, D8), throughout the duration of the time delay, of a third transistor (T6). This third transistor (T6) is connected by its base to the anode of the second diode (D8) through a resistor (R6), and by its emitter, to the cathode of a diode (D3) whose anode is connected, on the one hand to ground, and on the other hand to the collector of the first transistor (T2) of the absence of current detection circuit. The emitter and the base of the third transistor (T6) are connected together via a resistor (R7). The third transistor (T6) triggers at least a first relay (20), connected to the collector of the third transistor (T6), when it goes on. This first relay (20) is connected to an alert device (not shown) such as, for example, an audible alarm, an indicator light or a telephone call system. This first relay (20) remains activated until the electrical supply is restored. Advantageously, the collector of the third transistor (T6) is also connected to a second relay (30), via a second amplification circuit. This second circuit

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  amplifier comprising a capacitor (C6) and a resistor (R30) connected in series on the basis of a first transistor (T9). A diode, the anode of which is connected to ground, is connected to the common point of the resistor (R30) and the capacitor (C6). The emitter of the first transistor (T9) is connected to ground and the collector at the base of a second transistor (T10) via a resistor (R31). The emitter of this second transistor (T10) is connected to the negative pole of the accumulator (40) and the collector is connected to the second relay (30). This second relay (30) has the particularity of operating for a determined duration, for example a few minutes, after the 0o transition to the on state of the third transistor (T6). This second relay (30) also triggers an alert device (not shown), for example, a

  audible alarm, indicator light, or telephone call system.

  The circuit breaker test circuit is based on the verification of the neutral earth continuity of a circuit breaker. When a circuit breaker is in service, there is continuity between earth and neutral. However, when the

  circuit breaker has tripped, there is no longer any continuity between earth and neutral.

  When the transistor (T2) of the sector absence detection circuit turns on, it activates a third relay (10). Advantageously, the third relay (10) is a bistable relay, which means that it switches from a first position to a second position as soon as it receives an electrical pulse. This third relay (10) closes, when activated by this transistor (T2), a circuit establishing a loop between earth and neutral. This circuit includes a first resistor (R28), one terminal of which is connected to system earth T and the other to earth, when a first switch (11), controlled by the third relay (10), is in the closed position. . This circuit also includes a second resistor (R29), one of which is connected to the system neutral and the other terminal is connected, when a second switch (12) controlled by the third relay (10) is in the closed position, to the cathode of a diode whose anode is connected to the base of a transistor (T7). The emitter of this transistor (T7) is connected to the negative pole of the accumulator and the collector is connected through a first resistor (R24) to the third relay (10). A terminal of a

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  second resistor (R23) is connected to the common point between the base of the transistor (T7) and the first resistor (R24), the other terminal of the second resistor (R23) is connected to ground. The two switches (11, 12) are controlled simultaneously by the third relay (10) so that they have the same position, open or closed simultaneously. Thus, when the third relay (10) is activated by the first transistor (T2) of the current detection circuit, the two switches (11, 12) switch to the closed position. If the loop, formed between the earth and the neutral of the system, is closed, i.e. if there is neutral earth continuity, the transistor (T7), mounted on this loop, goes 1o from the state blocked in the on state. The change of state of this transistor (T7) again activates the third relay (10) which controls the opening of the two switches (11, 12). The open position of the two switches (11, 12) leaves the continuity test circuit open. If this loop is open, i.e.

  that there is no neutral earth continuity, the transistor (T7) remains in the off state.

  The absence of change of state of this transistor (T7), therefore keeps the continuity test circuit closed, which changes the state of a new transistor (T8). The base of this new transistor (T8) is connected, on the one hand to the collector of the first transistor (T2) of the current detection circuit through a resistor (R25) when the first switch (11) controlled by the third relay (10) is in the closed position, and on the other hand to earth, when the first switch (11) of the third relay is in the open position. The collector of this new transistor (T8) is connected to a terminal of a resistor (R26), the other terminal of which is connected to the cathode of a diode, the cathode of which is connected to the common point between the second resistor (R3 ) fixed and the transistor (T3) of the timing circuit. Thus the transition to the on state of the new transistor (T8) will interfere with the transistor (T3) of the timing circuit so that the timing delay will be reduced to a determined value, for example of the order of a few minutes. Thus, during a trip, the delay provided by the transistor (T3) of the delay circuit is shorter, the warning devices are therefore triggered after a shorter delay than in the case where there is no disjunction, that is to say in the case where the

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  transistor (T8) parasitizing the transistor (T3) of the timing circuit remains blocked. Thus during a first pulse, received from the transistor (T2) of the absence of current detection circuit, the two switches (11, 12) controlled by the third relay (10) change position to close the circuit for testing the neutral earth continuity of the circuit breaker. If continuity is detected by the transistor (T7) of the disjunction test circuit, this transistor (T7) sends a pulse which again switches the two switches (11, 12) to open the continuity test circuit. If, on the contrary, the transistor (T7) does not detect continuity, the two switches (11, 12) remain in the closed position, thereby triggering the transition to the on state of the transistor (T8) which will interfere with the transistor (T3) of the Advantageously, a warning light (L2), of LED type, is connected, on the one hand to the collector of the transistor (T8) interfering with the transistor (T8) of the timing circuit, and on the other hand

  goes to the negative pole of the accumulator (40) through a resistor (R27).

  Thus, this indicator light (L2) lights up as long as the transistor (T8) interferes with the transistor (T3) of the timing circuit, that is to say as long as the

circuit breaker is tripped.

  Advantageously, in addition to the device for supervising the electrical supply, the detection and alert system according to the invention also comprises at least one additional monitoring device such as a device for detecting a water leak, and / or a gas leak detection device and / or any other detection device. The device or devices used include, for example a sensor connected to a transmitter and a receiver connected to the system according to the invention. Whatever the detection device (s) used, these are connected, on the one hand, to the anode of a diode, and

  on the other hand to the negative pole of the accumulator (40) of the system according to the invention.

  The cathode (s) of the diode (s) are connected to the transistor (T6) triggering at least the first relay (20). In addition, the principle of this or these detection devices consists in closing a circuit, between the diode and the negative of the accumulator (40) as soon as an abnormal event, relative to the detection device, occurs. In other words, the detection circuit (s) of the

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  devices is normally open. Thus, as soon as an abnormal event occurs, the circuit of a detection device closes, then passing the transistor (T6) to the on state which triggers the first (20) and / or the

second relay (30).

  By way of example, Figures 2 and 3 show two alternative embodiments of a water leak detection device. Figure 2 shows a water leak detection device comprising a probe (60) which creates conductance when in contact with water. This probe (60) is connected, on the one hand to the negative pole of a power supply (61), and on the other hand by a resistor (R1), at the base of a first transistor (T1) of PNP type. The collector of this transistor (T1) is connected to the base of a second NPN type transistor (T2), the emitter of which is connected to the negative pole of the power supply (61), both by a relay (62 ) and by a light-emitting diode (L4). The collector of the second transistor (T2) and the emitter of the first transistor (T1) are connected together to the positive pole of the power supply (61). Thus, the two transistors (64,) are mounted so that at rest, that is to say in the absence of water leakage, the first transistor (64) is in the off state and, in this state, blocks the second transistor (65). The relay (62) controls a switch (63) for commissioning a coded transmitter (66). This coded transmitter (66) is associated with a receiver, corresponding to the code of the transmitter. This receiver is connected to the detection and alert system according to the invention. The water leak detection device is supplied by the supply (61) to the coded transmitter (64). At rest, the relay (62) deactivates the coded transmitter (66) by controlling the opening of the switch (63). During a water leak, conductance appears on the probe (60). This conductance causes the first transistor (64) to go on. This change of state also changes the second transistor (65) to the on state causing, on the one hand the lighting of the indicator light (L4), and on the other hand the work of the relay (62). The work of the relay (62) causes the switch (63) to close, putting the coded transmitter (66) into service. The signal emitted by the coded transmitter (66) is received by the receiver which triggers the closing of a circuit between the diode of the il 2779551 connection circuit of a detection device and the negative pole of the accumulator (40, Fig. 1) of the system according to the invention. Closing this circuit changes the third transistor (T6) to the on state which triggers

  warning devices as described above.

  Figure 3 is a variant of the water leak detection device of Figure 2 consisting only of removing the relay (62). In this variant, the coded emitter (71) connected in series between the emitter and the collector of the second transistor (65). The emitter of this second transistor (65) also comprising the indicator light (L4). In this arrangement, the second 1o transistor (65) behaves like a switch for commissioning the coded transmitter (71). At rest, the second transistor (65) is blocked, it acts as an open switch putting the coded transmitter (71) out of service. When a conductance appears on the probe (60), the second transistor (65) becomes conducting, via the transition to the conducting state of the first transistor (64), and therefore acts as a closed switch then putting the coded transmitter

(71) in service.

  It is understood that the system according to the invention is simple to set up since it suffices to connect it to an electrical outlet. In addition, it makes it possible to differentiate a power cut due to a disjunction, from a power cut due to a power cut in the distribution network. This differentiation is associated with alert devices that warn the user after different delays depending on the type of cut. Indeed, during a power outage due to a power outage from the distribution network, it is not necessary to notify the user immediately since electricity can be restored quickly. On the other hand, if the supply is cut off following a trip, it is necessary to warn the user quickly since the supply will only be restored if the circuit breaker is put back into service. Finally, the system according to the invention also makes it possible to adapt

  easily from other detection device.

  It is clear that other modifications within the reach of those skilled in the art fall within the scope of the invention.

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Claims (10)

  1. Detection and alert system characterized in that it is connected to the electricity distribution network by a standardized electrical outlet having an earth connection, that it comprises a circuit for detecting the absence of current comprising a trip test circuit, this trip test circuit being connected to means (T3, T8) for determining a different delay after which alert means are triggered according to the detection of absence of current and / or disconnection, the alert means being triggered at short notice in the event of detection of absence of current with disconnection and at long time in the case of detection of absence of current without disjunction.   2. Detection and alert system according to claim 1, characterized in that the absence of current detection circuit comprises a transistor (T2) which is in the off state during the presence of current and when on state i5 during a power failure, the on state of the, transistor activating the circuit   circuit breaker and a timing circuit.   3. Detection and alert system according to claim 1, characterized in that the timing circuit comprises a transistor (T3), a capacitor (C1l) and a plurality of resistors (R2, R3, R4), the characteristics of the capacitor (C1) and the plurality of resistors (R2, R3, R4) being determined as a function of the time delay chosen by the user for triggering the alert means when a detection of absence of current without tripping , this period being between one and four hours.   4. Detection and alert system according to one of claims 1 to 3,   characterized in that the circuit-breaker test circuit comprises a relay (10) activated by the transistor (T2) of the circuit for detecting no current, activation of the relay (10) makes it possible to check the continuity between the earth and the neutral of the electrical outlet circuit, via a second transistor (T7), which turns on to activate the relay again in the event of continuity and which, if not, remains blocked to leave in the state the relay (10), 13 2779551   the blocked state of this second transistor (T7) decreasing the delay of the timing circuit, by means of the transition to the passing state of a third   transistor (T8) connected to the second transistor (T3) of the timing circuit.   5. Detection and alert system according to one of claims 1 to 4,   characterized in that the alert means are triggered by a first relay (20) activated by a transistor (T6), which remains in the off state for a determined period, the first relay (20) remaining activated as long as it there is no power supply, and / or by a second relay (30) activated by the transistor (T6), which remains in the off state for a determined period, the second relay (30) remaining activated for a duration chosen by the user, the delay after which the first and / or the second relay are activated is   determined by the timing circuit.   6. Detection and alert system according to one of claims 1 to 5,   characterized in that the system includes a circuit for verifying   connection to the electrical outlet.   7. Detection and alert system according to claim 6, characterized in that the connection verification circuit comprises a switch (51) with two positions, mounted on the phase, which, in a first position puts the system into service , and in a second position turns off the system and connects to a neon lamp (50) mounted on the ground, this neon lamp (50) testifying, when it is on, on the one hand that the system is out of service , and secondly that the socket to which the system is connected is   correctly connected to the electrical distribution network.   8. Detection and alert system according to one of claims 5 to 7,   characterized in that the system comprises means for detecting water leakage and / or gas leakage or the like, these means comprising an electric circuit open in normal condition and closed upon detection of a water leakage and / or gas or other, the closing of this circuit activating the first (20)   and / or the second relay (30) of the alert means. 14 2779551   9. Detection and alert system according to claim 8, characterized in that the alert means comprise a telephone call device   and / or an audible alarm and / or an indicator light.   10. Detection and alert system according to claim 8 or 9, characterized in that the water leak detection device comprises a probe (60) creating a conductance in the presence of water, a first transistor (64) connected to the probe (60) and to a second transistor (65), the first transistor (64) being in the off state in the absence of conductance on the probe (60) and in the on state otherwise , the second transistor (65) being in the on state when the first transistor (64) is on, the on state of the second transistor causing the circuit activating the first (20)   and / or the second relay (30) of the alert means.