FR2896345A1 - CIRCUIT BREAKER COMPRISING SUBSIDIARY CURRENT CUTTING MEANS - Google Patents

Abstract

The present invention relates to a circuit breaker (1) comprising an electrical input terminal (10) intended to be connected to an accumulator battery (300), an electrical output terminal (20), contact means (2) , 3) adapted to close or open the electrical contact between the two electrical terminals, supply means (104, 105) contact means connected to the input electrical terminal, and control means (100, 106). , 106A) contact means connected to a power supply (103A) .In accordance with the invention, the circuit breaker comprises means for detecting (102) a voltage on the input electrical terminal, a delay (100A) adapted to be triggered and stopped by the detection means and to send a signal for the opening of the electrical contact between the two electrical terminals, and an electric circuit (200) comprising a capacitor (201) which is connected to said electrical terminal of 'Entrance.

Description

TECHNICAL FIELD TO WHICH THE INVENTION RELATES The present invention

  generally relates to circuit breakers for accumulator batteries. It relates more particularly to a circuit breaker comprising an electrical input terminal intended to be connected to an accumulator battery, an electrical output terminal, contact means adapted to close or to open the electrical contact between the two electrical terminals. input and output means, supply means of the contact means connected to the input electrical terminal, and control means of the contact means electrically connected to a power supply connected to the input electrical terminal. BACKGROUND ART A circuit breaker of the aforementioned type is generally intended to be connected, on the one hand, to an alternator adapted to recharge said accumulator battery, and, on the other hand, to an electric starter motor. a main engine of a vehicle. The control means of its contact means are then adapted, depending on the off position, preheating, or ignition of a ignition key in the neiman of the vehicle, to control the opening or closing of its contact means. so as to isolate said accumulator battery from the alternator and the electric motor. Currently, the control means and the power supply means of the contact means of the circuit breaker are connected to its input electrical terminal so that they are constantly electrically connected to the accumulator battery, whatever the position of the means of contact.

  The main disadvantage of such a circuit breaker is that if, for any reason such as for example the replacement of the storage battery, the electrical input terminal of the circuit breaker is no longer electrically connected to the battery. battery, its electrical circuits cease to be powered so that its contact means retain their open or closed position until the circuit breaker is again powered by the battery. However, if this temporary disconnection was due to a change of accumulator battery by a new battery and that the installer plugs the latter upside down while the contact means have remained in the closed position, this connection may cause electrical problems in the entire electrical network of the vehicle. Furthermore, if, during this temporary disconnection, a short-circuit occurs in the vehicle's electrical network, reconnecting the battery may generate overvoltages potentially dangerous for the person handling the accumulator battery and for the whole the vehicle's electrical network, particularly in explosive atmospheres. OBJECT OF THE INVENTION In order to overcome the above-mentioned drawback of the state of the art, the present invention proposes a circuit breaker adapted, when no longer supplied with current, to automatically open its contact means. More particularly, it is proposed according to the invention a circuit breaker as defined in the introduction, wherein there is provided means for detecting a voltage on the input electrical terminal, a timer provided in said control means and adapted, on the one hand, to be triggered and stopped by the detection means, and, on the other hand, to send a signal for the opening of the electrical contact between the two electrical input and output terminals, and an electrical circuit comprising a capacitor which is connected on one side to a fixed potential point and on the other to said input electrical terminal.

  Thus, thanks to the invention, when the circuit breaker is no longer powered by the accumulator battery, the capacitor, which is electrically connected, on the one hand, to the supply means of said contact means, and, on the other hand, to the power supply of said control means of said contact means, is discharged so as to continue to supply these various electrical elements of the circuit breaker, which allows in particular for the timer to start counting down the time during a predetermined period, then possibly to control the opening of the contact means if the detection means have not detected in the meantime a restoration of the power supply input of the circuit breaker. This opening prevents any damage to the vehicle's electrical system if the battery has been disconnected and reconnected in reverse. It also makes it possible to avoid the appearance of potentially dangerous overvoltages for the vehicle electrical network insofar as the contact means block the current at the output of the accumulator battery.

  According to a first advantageous characteristic of the invention, said electric circuit comprises in parallel, between the capacitor and said electrical input terminal, an electrical resistance and a diode whose cathode is connected to the input electrical terminal.

  Thus, the resistor makes it possible, when an accumulator battery is connected to the electrical input terminal of the circuit breaker, to limit the charging current of the capacitor so as not to damage it. The diode allows for the discharge current of the capacitor, when no accumulator battery is no longer connected to the electrical input terminal of the circuit breaker, to supply the various electrical circuits of the circuit breaker without passing by said resistor, thus limiting the resistive losses. Advantageously, said electrical circuit comprises, in parallel with the capacitor, a Zener diode whose anode is connected to the point of fixed potential.

  Thus, if an overvoltage appears at the terminals of the electrical circuit, this Zener diode prevents the capacitor from experiencing this overvoltage, all of the current then passing through this Zener diode. Advantageously, said detection means are adapted to detect a non-zero voltage on the input electrical terminal.

  Thus, the detection means trigger the delay as soon as the voltage on the input electrical terminal is canceled, that is to say as soon as the accumulator battery and the electrical input terminal of the circuit breaker do not are more properly electrically connected. Advantageously, said detection means are adapted to detect a voltage greater than a threshold value on the input electrical terminal. Thus, as soon as the voltage delivered by the accumulator battery becomes lower than a threshold value (such as the voltage below which the contact means can no longer change state), the detection means trigger the delay in such a way that the capacitor supplies the various electrical elements of the circuit breaker for the opening of its contact means. Advantageously, the timer is adapted to send an opening signal about one minute after being triggered.

  Thus, when said detection means detect a voltage drop on the electrical input terminal of the circuit breaker, they trigger this delay which sends, about a minute later, an opening signal of the contact means if the detection means have not detected in the meantime a restoration of the voltage on the electrical input terminal. This waiting makes it possible to ensure that the control means do not open the contact means during a voltage drop at the input of the circuit breaker inherent in its normal operation, for example during the momentary phase of starting the motor of the motor. vehicle.

  On the other hand, the sending of the opening signal by the delay time must take place after a latency time shorter than the capacitor discharge time (so that the control and power supply means are able to open the contact means at the end of this latency) and the time required to replace a battery (to ensure that the contact means are open when connecting the new battery), that is why it here is chosen equal to one minute. Other advantageous and non-limiting features of the circuit breaker according to the invention are the following: the circuit breaker comprises other means for detecting the open or closed state of the contact means; the timer is adapted to trigger when the other detection means detect the closed state of the contact means; - The circuit breaker comprises an input diode whose anode is directly connected to the electrical input terminal and whose cathode is connected to said electrical circuit; and the point of fixed potential constitutes the electric ground of the circuit breaker. DETAILED DESCRIPTION OF AN EXEMPLARY EMBODIMENT The following description with reference to the accompanying drawings given by way of non-limiting examples, will make it clear what the invention consists of and how it can be achieved. In the accompanying drawings: FIG. 1 is a schematic perspective view of a circuit breaker according to the invention; and FIG. 2 is a diagrammatic view of the electrical circuits of the circuit breaker of FIG. 1. FIG. 1 shows a circuit breaker 1 comprising a parallelepiped-shaped casing 1A formed by two distinct parts intended to be fitted together. 1 on one of its side walls, the housing 1A carries two electrical input terminals 10 and output 20 which are identical and which each have a body 11, 21 elongate shape extending from the inside of the housing 1A to beyond its side wall.

  One of the ends of each of these bodies 11, 21, that disposed inside the housing 1A, is connected to a contact element 12, 22 fixed. The two contactor elements 12, 22 have a square section, a small thickness and form a flat face facing the inside of the housing 1A. The other end of each of these bodies 11, 21 is pierced by a cylindrical inner housing opening into which can be crimped a stripped end of a power supply cable. The electrical input terminal 10 can thus be electrically connected to a battery of the vehicle provided with the circuit breaker 1. The electrical output terminal can be connected for example to an electric motor for starting the main engine of the vehicle. vehicle and an electric alternator suitable for recharging the accumulator battery. The two electrical input and output terminals 20 are here made of a single piece of silver copper. They are held on the housing 1A by means of a ring 14, 24 being formed with said terminals and a nut 15, 25 which sandwich the side wall of the housing. The housing 1B accommodates all the electrical elements of the circuit breaker 1, in particular contact means 2, 3 adapted to close or open the electrical contact between the two electrical input terminals 10 and 20 of the output cutter. circuit 1, and an electronic circuit 30 for controlling contact means 2, 3. These contact means 2, 3 comprise in particular a contact bridge 3 constituting a U-section beam whose two branches are oriented inwardly. of the housing 1A and whose upper face is turned towards the flat faces of the contacting elements 12, 22 of the electrical input terminals 10 and output 20. This contact bridge 3 has a length which allows its upper face to simultaneously enter in contact with the two flat faces of the contacting elements 12, 22. The contact bridge 3 also has a central opening for attachment to a movable shaft 2A engaged in this opening v er. This movable shaft 2A has at mid-height a flange 4 and at one of its ends a threaded portion. A compression spring 5 is engaged on this shaft so as to bear against the flange 4. The contact bridge 3 is positioned against this compression spring 5. A nut 6 is screwed onto the threaded portion of the shaft mobile 2A so as to maintain the contact bridge 3 in pressure against the compression spring 5. The movable shaft 2A is adapted to translate between two stable positions. In a first stable position, the contact bridge 3 is arranged at a distance from the contacting elements 12, 22, and in a second stable position, the contact bridge 3 bears against these contacting elements so that it closes the electrical contact between the two electrical input and output terminals 20. The movable shaft 2A is preferably made of non-magnetic material. The compression spring 5 serves, when the movable shaft 2A is in second stable position, to correctly maintain the contact bridge 3 against the contact elements 12, 22 so that the passage of electric current from one electrical terminal to the other generates few resistive losses. The contact means 2, 3 also comprise a bistable operating device 2 connected to the movable shaft 2A and able to place the latter in its first and second stable positions.

  For this, as shown more particularly in FIG. 2, it comprises, inside a cylindrical carcass, on the one hand, an electromagnetic coil 2B adapted to create a magnetic field which generates a displacement force in translation of the mobile shaft 2A, and, on the other hand, an arrangement of a ramp connected to the movable shaft 2A and fixed pins cooperating with this ramp to guide the movable shaft 2A between its first and second stable positions and for the keep it there. The electronic circuit 30 of the circuit breaker 1 comprises supply means 104, 105 of the electromagnetic coil 2B and control means 100, 106, 106A for controlling said supply means 104, 105. More specifically, the circuit electronics 30 comprises a terminal block 31 whose input is connected, via a first power supply cable 101, to the electrical input terminal 10 of the circuit breaker 1. This input of the terminal block 31 is connected to a track input channel of the electronic circuit 30. This input track comprises an input diode 101A whose anode is connected to the terminal block 31 and whose cathode is connected to the power supply means 104, 105 and to the control means 100, 106, 106A of the electromagnetic coil 2B. This input diode 101A is adapted to block the upward current to the input electrical terminal in the event of polarity reversal or failure of the accumulator battery 300. This input diode 101A may optionally be of the type Germanium to reduce voltage drops on the input track.

  More specifically, the supply means 104, 105 of the electromagnetic coil 2B comprise a first supply track 104 which links the cathode of the input diode 101A to an output of the terminal block 31 of the electronic circuit 30, which is itself connected. electrically at one of the terminals of the electromagnetic coil 2B.

  The supply means 104, 105 also comprise a second supply track 105 which, via the terminal block 31, links the other terminal of the electromagnetic coil 2B to a MOS transistor 106A, itself connected to the electrical mass of the circuit breaker 1. Said control means 100, 106, 106A comprise for their part a microprocessor 100 provided with an output 106 whose state of its potential (up or down) controls the open or closed position of the transistor 106A, and thus the passage of the electric current in the electromagnetic coil 2B. The state of this output 106 therefore depends on the appearance of a magnetic field making it possible to modify the position of the contact bridge 3.

  The microprocessor 100 is supplied with current by a power supply 103A connected by an electrical track 103 to the cathode of the input diode 101A. The microprocessor 100 further comprises three inputs on which depends the state of the potential of its output 106.

  A first of these inputs is connected, via an electrical track 108 and through the terminal block 31, to the contact bridge 3 of the circuit breaker 1, thus constituting means for detecting the open or closed state of the contact means. 2, 3. Therefore, when an electric current passes from the electrical input terminal 10 to the electrical output terminal 20, the microprocessor detects an electrical potential on its first input and deduces that the contact bridge 3 is in open position. A second of these inputs is connected by an electrical track 102 to the input track of the electronic circuit 30, on the anode side of the input diode 101A, thus constituting means for detecting a voltage on the terminal Thus, when the microprocessor 100 detects a potential greater than a predetermined threshold on its second input, it deduces therefrom that an accumulator battery 300 is electrically connected to the electrical input terminal 10 of the cutter. On the other hand, if this potential is lower than this threshold, it deduces that this electrical connection has been broken or that the accumulator battery 300 is weak. This predetermined threshold may correspond, for example, to a zero voltage or to a value of the voltage delivered by the battery below which the electromagnetic coil 2B is no longer sufficiently supplied with current to be able to open the contact bridge 3. A third of these inputs is connected by an electrical track and by an auxiliary electrical wire 107 to a terminal of a neiman 107A of the vehicle whose other terminal is connected to the cathode of the input diode 101A of the electronic circuit 30. Thus, when the neiman is in the preheating or starting position, and not in the stopped position, the microprocessor detects an electrical potential on its third input. According to a particularly advantageous characteristic of the invention, the control means of the circuit breaker 1 comprises a delay 100A included in the microprocessor 100, and the circuit breaker 1 comprises an electric circuit 200, provided with a capacitor 201, which is connected, on one side, to the cathode of the input diode 101A, and, on the other hand, to the electrical ground of the circuit breaker 1. The delay is intended to trip when the electric potential of the second input the microprocessor 100 is canceled, provided that the first input of the microprocessor 100 detects that the contact means 2, 3 are in the open position. The capacitor 201 here has a capacity of about 10 milliFarad. The electrical circuit 200 further comprises, in parallel, between the capacitor 201 and the cathode of the input diode 101A, an electrical resistance 204, here having a resistivity of 1000 ohms, and a diode 203 whose anode is connected to the side. of the capacitor 201. This diode 203 makes it possible, when the accumulator battery 300 is electrically connected to the electrical input terminal 10 of the circuit breaker 1, to pass the entire charging current of the capacitor 201 through the resistor 204. , which limits the intensity of this current so as not to degrade the performance of the capacitor 201. Moreover, when no accumulator battery is no longer connected to the electrical input terminal 10 of the circuit breaker 1 this diode 203 makes it possible to pass the discharge current of the capacitor 201 without causing resistive losses. Advantageously, the electrical circuit 200 also comprises a Zener diode 202 connected in parallel with the capacitor 201 and intended to protect the latter from any overvoltages coming from the electrical input terminal 10. The anode of this Zener diode is connected to ground electric circuit breaker 1 so that it is adapted to directly pass the electric current from the electrical input terminal 10 to said electrical ground when the value of the voltage across its upper limit exceeds the value of its nominal voltage, which is here 16 volts while the nominal voltage of the accumulator battery 300 is 12 volts, so as to bypass the capacitor 201. In operation, the accumulator battery 300 being electrically connected to the electrical terminal of input 10 of the circuit breaker 1, the power supply 103A of the circuit breaker 1 supplies power to the microprocessor 100 which is thus adapted to monitor er the state of the electric potentials of its three inputs and to modify accordingly the state of the potential of its output 106. When the user of the vehicle inserts a key of contact in the neiman 107A of the vehicle and puts it in preheating position or start, the third input of the microprocessor 100 detects an electrical potential and triggers the momentary closing of the transistor 106A at its output.

  An electric current then passes through the electromagnetic coil 2B, which generates a force capable of moving the movable shaft 2A to permanently close the contact bridge 3 so that the current passes from the electrical input terminal 10 to the electrical terminal of output 20 of the circuit breaker 1.

  The first and second inputs of the microprocessor 100 then both detect an electrical potential signifying that the contact bridge 3 is in the closed position and that the accumulator battery 300 is correctly connected to the circuit breaker 1. A fraction of the current passing through the input electrical terminal is deflected to supply the power supply 103A of the microprocessor 100 and to charge, through the electrical resistance 204, the capacitor 201. This current fraction can come from the accumulator battery 300 or the alternator if the latter charges the battery. If, for some reason, the accumulator battery 300 stops supplying the circuit breaker 1 with current while the contact bridge 3 is in the closed position, the capacitor 201 begins to discharge through the diode 203 of so that the microprocessor 100 continues to be supplied with current. Simultaneously and regardless of the position of the ignition key in the neiman 107A of the vehicle, the second detection input 102 of a voltage on the electrical input terminal 10 triggers the delay 100A of the microprocessor 100. After a waiting period of about one minute, if said detection means 102 have not detected a restoration of the input supply of the circuit breaker 1, the microprocessor 100 triggers the closing of the transistor 106A so that the electromagnetic coil, which is it also fed by the capacitor 201, creates a magnetic field causing the opening of the contact bridge 3 of the circuit breaker 1. Thus, when the accumulator battery 300 is again connected to the electrical input terminal 10 of the cutter circuit 1, the contact means 2, 3 are in the open position which avoids the occurrence of overvoltages or short circuit potentially dangerous for the vehicle and for its driver. On the other hand, if the detection means 102 detect a restoration of the input supply of the circuit breaker 1 during the wait time of one minute, the microprocessor stops the delay 100A so that it does not send no signal triggering the opening of the contact means 2, 3. The present invention is not limited to the embodiment 5 described and shown, but the art can apply any variant within his mind.

Claims (4)

  1. A circuit breaker (1) comprising: - an electrical input terminal (10) intended to be connected to an accumulator battery (300), - an electrical output terminal (20), - contact means ( 2, 3) adapted to close or open the electrical contact between the two electrical input (10) and output (20) terminals, - supply means (104, 105) of the contact means (2, 3 ) connected to the input electrical terminal (10), and - control means (100, 106, 106A) of the contact means (2, 3) electrically connected to a power supply (103A) connected to the electrical terminal input (10), characterized in that it comprises means (102) for detecting a voltage on said input electrical terminal (10), a delay (100A) provided in said control means (100, 106). , 106A) and adapted, on the one hand, to be triggered and stopped by the detection means (102), and, on the other hand, to send a signal for the opening e of the electrical contact between the two electrical input (10) and output (20) terminals, and an electrical circuit (200) comprising a capacitor (201) which is connected on one side to a point of fixed potential and of the other at said input electrical terminal (10).   2. Circuit breaker (1) according to claim 1, characterized in that said electric circuit (200) comprises in parallel, between the capacitor (201) and said electrical input terminal (10), an electrical resistance (204) and a diode (203) whose cathode is connected to the input electrical terminal (10).   3. Circuit breaker (1) according to one of claims 1 and 2, characterized in that said electrical circuit (200) comprises in parallel capacitor (201) a Zener diode (202) whose anode is connected to the point fixed potential.   4. Circuit breaker according to one of claims 1 to 3, characterized in that said detection means (102) are adapted to detect a non-zero voltage on the input electrical terminal (10). . Circuit breaker according to one of claims 1 to 3, characterized in that said detection means (102) are adapted to detect a voltage greater than a threshold value on the input electrical terminal (10). 6. A circuit breaker (1) according to one of claims 1 to 5, characterized in that the timer (100A) is adapted to send an opening signal about one minute after being triggered. 7. Circuit breaker (1) according to one of claims 1 to 6, characterized in that it comprises other means (108) for detecting the open or closed state of the contact means (2, 3). . 8. Circuit breaker (1) according to claim 7, characterized in that the timer (100A) is adapted to be triggered when the other detection means (108) detect the closed state of the contact means (2, 3). . 9. Circuit breaker (1) according to one of claims 1 to 8, characterized in that it comprises an input diode (101A) whose anode is directly connected to the electrical input terminal (10). and whose cathode is connected to said electrical circuit (200). 10. Circuit breaker (1) according to one of claims 1 to 9, characterized in that the point of fixed potential is the electric ground of the circuit breaker (1).