FR2896086A1 - Circuit-breaker for storage battery in motor vehicle, has comparison unit for comparing parameter value with threshold value to provide information to processing unit which transforms information into control order to open contact bridge - Google Patents

Abstract

Circuit-breaker (1) has a contact bridge (3) closing/opening an electrical contact between input and output electrical terminals (100, 200), where the terminal (100) is connected to a storage battery. An electronic circuit (10) has a storage unit to store a threshold value of a parameter associated to an electric current passing via the circuit-breaker. The circuit has a comparison unit to compare a parameter value determined by electrical wires with the threshold value for providing information to a processing unit transforming the information into a control order to open the contact bridge.

Description

TECHNICAL FIELD TO WHICH THE INVENTION RELATES The present invention

  generally relates to the stern-circuit for 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, and an electronic control circuit means contact. BACKGROUND ART There is already known a circuit breaker of the same type, the output terminal of which is connected, on the one hand, to an alternator adapted to recharge said accumulator battery, and, on the other hand, to an electric motor. electric starter of a main vehicle engine such as an internal combustion engine. Such a circuit breaker generally comprises an electronic control circuit of the contact means adapted to control the opening or closing of the contact means when it receives the order from a microprocessor global control of the various functions of the motor vehicle. Generally, this microprocessor receives information as to the off position, preheating, or ignition of the ignition key in the neiman of the vehicle and, based on this information, transmits to the electronic circuit the command to open or close command of:; means of contact. Said opening or closing command is thus decentralized with respect to the circuit breaker.

  Moreover, there exists, in order to protect the battery and the alternator, disjunction means, arranged on the electrical cable linking these two elements, adapted to open the electric circuit when a magnitude of the electric current passing through this circuit (for example the intensity) exceeds a predetermined threshold value. These disjunction means are for example fuses that need to be replaced after a short circuit, or manually resettable circuit breakers. The main drawbacks of such a circuit breaker are, on the one hand, that the electronic circuit is not adapted to generate quickly and by itself an order of opening control of the contact means during a co-operation. art-circuit, and, secondly, that the disjunction means are not reusable immediately and require manual intervention for the electrical circuit can operate again. In addition, these disjunctive means are not adapted to protect the battery and the electric motor during the discharge cycle of the accumulator battery, in particular when starting the main engine of the vehicle by the electric motor. OBJECT OF THE INVENTION In order to overcome the aforementioned drawbacks of the state of the art, the present invention proposes a circuit breaker adapted to electrically isolate the battery of any electric device during a short circuit. . More particularly, according to the invention, there is provided a circuit breaker as defined in the introduction, in which the electronic circuit comprises means for storing at least one threshold value of at least L n parameter associated with the passing electrical current. by the circuit breaker, means for determining at least one value of said parameter of the circuit breaker in operation, and means for comparing the value determined by the determining means with said threshold value adapted to provide information to processing means adapted to transform this information er a command order of the contact means. Thus, thanks to the invention, the circuit breaker is adapted to rapidly electrically isolate the accumulator battery of all the electrical devices of the vehicle when it detects a short circuit. This circuit breaker is therefore adapted to protect not only said electrical appliances by cutting off their power supply during a short circuit, but also the battery itself during its charge cycle by the alternator. In addition, the circuit breaker can let the power flow again autonomously when it detects the end of the short circuit. Moreover, the use of such a circuit breaker makes it possible to provide electrical terminals for entry and exit of lower section in so far as said electrical terminals are no longer liable to have to pass important currents linked to short circuits. circuit. The section of the input and output electrical terminals decreasing, the overall cost of the circuit breaker decreases accordingly.

  According to a first advantageous characteristic of the circuit breaker according to the invention, each threshold value of a parameter associated with the electric current passing through the circuit breaker depends on the direction of said current. Thus, the threshold value is different during the charging phase of the battery by an alternator and during the supply phase of the starting motor of the main engine by the accumulator battery. Indeed, if the currents delivered by the alternator in the accumulator battery normally never exceeds 200 amps, however, the currents delivered by the battery in the starter motor of the main engine of the vehicle can exceed this value. The circuit breaker thus makes it possible to adapt the threshold value in the sense of the current entering or leaving the accumulator battery. Advantageously, the determination means comprise means for measuring at least one value of a quantity associated with the electric current passing through one of the electrical input or output terminals of the circuit breaker. Thus, it is possible to provide that the determination means make a measurement of the current passing through the circuit breaker and then convert the value of the measured quantity into a value of a characteristic parameter of a short circuit. For example, the circuit breaker can measure a potential at a point of the electrical input terminal and then transform the potential mESUré into a potential drop rate which is a parameter for detecting a possible short circuit. Other advantageous and non-limiting characteristics of the circuit breaker according to the invention are the following: the determination means comprise calculation means which read the value of the quantity measured by the measuring means to find the value of the cutting parameter. -circuit in operation; the electrical input or output terminal on which said measuring means make a measurement of the value of the quantity associated with the electric current passing through this terminal has a hollow body; one of the quantities whose value is measured by said measurement means is an electric potential measured at a point of one of the electrical input or output terminals; said storage means stores threshold values of voltage drop speed; said threshold voltage drop speed threshold values are between 0.05 and 0.5 volts per second; one of the quantities measured by said measuring means is the intensity of the current flowing in the circuit breaker; said storage means store threshold values of intensity of electric current associated with durations; and the circuit breaker comprises shock and / or inclination detection means adapted to lower the value of said threshold value when they detect an impact and / or an inclination. 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 perspective view of the inside of a housing of a circuit breaker according to the invention; FIG. 2 is a schematic view of a current breaking device at the output of an accumulator battery; - Figure 3 is a schematic sectional view of an electrical input terminal according to the invention of the circuit breaker of Figure 1; - Figure 4 is a schematic sectional view of an alternative embodiment of the electrical input terminal of Figure 2; Fig. 5A is a diagrammatic sectional view of means for attaching a power supply cable with a storage battery of the power cut-off device of Fig. 2; - Figure 5B is a schematic perspective view of the attachment means of Figure 5A; Figure 6 is a schematic top view of the circuit breaker of Figure 1; FIG. 7 is a schematic view of part of the electrical circuits of an electronic board of the circuit breaker of FIG. 1; and FIG. 8 is an opening diagram of the circuit breaker of FIG.

  In Figure 1, there is shown a circuit breaker 1 according to the invention. This circuit breaker 1 comprises a parallelepiped-shaped casing 1A formed by two distinct parts designed to be fitted one above the other to define a housing I B.

  On one of its side walls, the housing 1A carries two identical electrical terminals, an electrical input terminal 100 and an electrical output terminal 200, each having a body 101, 201 of elongated shape extending from the inside of the housing. housing 1A to beyond its side wall. A first end of each of these bodies 101, 201, that disposed inside the housing 1A, is connected to a contact member 102, 202 fixed. These two electrical terminals 100, 200 are here made of silver-plated copper. The two contactor elements 102, 202 have a square section and a small thickness. They form a plane face turned towards the inside of the casing 1A. The housing 1B accommodates all the electrical equipment of the circuit breaker 1. One of these electrical devices is contact means 3 adapted to close or open the electrical contact between the two electrical terminals 100 and 200 output output of the circuit breaker 1. These contact means comprise in particular a contact bridge 3 constituting a U-section beam whose two branches are oriented towards the inside of the housing 1A and whose upper face is turned towards the plane faces of the elements. contactors 102, 202 of the electrical terminals 100 and 200 output output. This contact bridge 3 has a length that allows its upper face to simultaneously be in contact with the two flat faces of the contact elements 102, 202. The bridge contact 3 also has a central opening for attachment to a movable shaft 2A engaged in this.:e opening.

  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 polish 3 against the compression spring 5. The movable shaft 2A is adapted to translate between two stable posilions. In a first stable position, the contact bridge 3 is arranged at a distance from the contacting elements 102, 202, and in a second stable position, the contact bridge 3 bears against these contacting elements. The movable shaft 2A is preferably made of non-magnetic material. A bistable operating device 2 of cylindrical shape is connected to the movable shaft 2A and is able to move it in translation between its first and second stable positions. The housing 1A also internally comprises an electronic circuit 10 for controlling the bistable operating device 2. This electronic circuit 10 comprises in particular a microprocessor. The set of electrical equipment contained in the housing 1A 15 thus makes it possible to open and close the electrical contact of the electrical circuit to which the circuit breaker 1 is connected. As shown particularly in FIG. electrically isolating an accumulator battery 300. More specifically, the second end of the electrical input terminal 100 of the circuit breaker 1 is connected via a power supply cable 150 to the positive terminal of the accumulator battery 300, the negative terminal of which is connected to an electrical ground. The circuit breaker 1 and the accumulator battery 300 are generally arranged in a battery box 301 fixed to the frame 600 of a motor vehicle which forms this electric mass. The second end of the electrical output terminal 200 of the circuit breaker 1 is itself connected by two separate electrical circuits, on the one hand, to a suitable alternator 500, when it is rotated by the main motor ( not shown) of said vehicle, producing an electric current for charging the accumulator battery 300, and, secondly, an electric motor 400 adapted to rotate the main motor of the vehicle to start it. This main engine may for example be an internal combustion engine. As shown in Figure 3, according to an advantageous characteristic of the circuit breaker 1 according to the invention, for its mechanical and electrical connection to the power supply cable 150, the body 101 of the electrical input terminal 100 is hollow, here over its entire length, and forms, on the side of its second end intended to be connected to said cable, a housing 103 opening for receiving a stripped portion 151 of this cable. The housing 103 is defined inside a tubular wall 104 of the body 101 having a thickness of about 2 millimeters. The inner diameter of the tubular wall 104 of the body 101 corresponds to the outer diameter of the stripped portion of the cable and is generally between 5 and 10 millimeters, it is here equal to 6 millimeters. This tubular wall 104 is, thanks to its small thickness, capable of being locally plastically deformed so that, once the stripped portion 151 of the power supply cable 150 engaged in the housing of the electrical input terminal 100, it is possible to crimp the power supply cable 150 with the terminal so that they form a one-piece assembly inseparable after crimping.

  Advantageously, as shown in FIG. 3, the housing 103 opens out of the body 101 of the electrical input terminal 100 near its first end by a lateral orifice 107 having an axis perpendicular to the axis of said terminal. and about 1 millimeter in diameter. This lateral orifice 107 allows the passage of an electric wire 111. A seal (not shown) can be arranged in this lateral orifice 107 so as to prevent water particles from entering the electrical terminal of entry 100 through this orifice. The body 101 of the electrical input terminal 100 also laterally has two peripheral grooves 108 for receiving an electrical wire 113, 114. These two peripheral grooves 108 are arranged near the contacting element 102. a shallow depth of about 3 millimeters, and allow to maintain laterally an electric wire to eventually crimp the bottom of the throat to fix it. For its attachment to the casing 1A of the circuit breaker 1, as shown more particularly in FIG. 3, the body 101 of the electrical input terminal 100 bears on the outer face of its tubular wall 104 a thread 105 adjacent to the element contactor 102 for receiving a fixing nut (not shown). The electrical input terminal 100 is therefore inserted into an opening in the side wall of the casing 1A of the circuit breaker 1 until the contactor element 102 is applied to one of the faces of this side wall.

  The fixing nut is then screwed onto the thread 105 until it bears against the other face of this side wall. Thus, this side wall is sandwiched between the fixing nut and the contactor element 102 so that the electrical input terminal 100 and the housing 1A form a rigid unbreakable assembly.

  According to a first variant not shown of the electrical input terminal, the body of the electrical input terminal may carry a peripheral ring disposed at a distance from the contact member near which then extends the thread. Thus, the side wall of the housing, for fixing the terminal, is sandwiched between the fixing nut and this peripheral ring so that the contacting element is disposed at a distance from the side wall of the housing of the cutter. circuit. According to a second variant, more particularly illustrated by FIG. 4, for securing to the side wall of the casing 1A of the circuit breaker, the body 101 of the electrical input terminal 100 externally carries a peripheral ring 106 intended to be crimped into the side wall of the housing 1A by thermodeformation of this wall. In this second variant, the contactor element 102 may also be placed at a distance from the side wall of the casing 1A of the circuit breaker 1. In these first and second variants, the peripheral grooves 108 and the lateral orifice 107 of the electrical terminal input 100 are, when the latter is secured to the housing 1A, disposed within the housing 1A. Thus, depending on the configuration of the electrical input terminal and in particular its fixing means, the lateral orifice 107 and the peripheral grooves 108 may be arranged, when the electrical input terminal 100 is secured to the housing 1A of the cutter. circuit 1, either inside the housing 1A, or at its side wall. In the latter case, as shown more particularly in Figure 3, the side wall of the housing 1A can be pierced by oblique channels 112 allowing the passage of electrical son 111, 113, 114 into the housing 1A of the circuit breaker 1 while opening on one side, at the orifice 107 or the peripheral grooves 108, and, on the other, inside the housing 1A. However, the method of fixing the power supply cable 150 remains identical to that previously described and is achieved by crimping one end of the cable in the housing 103 of the electrical input terminal 100. Advantageously, as shown in FIGS. 5A and 5B, the other end of the power supply cable 150 comprises a second stripped portion 152 fixed by attachment means to the positive terminal 301 of the accumulator battery 300. These means fasteners constitute a covered terminal 160 having a cylindrical base 162 provided on its side face with a lug 161 adapted to be crimped on the second stripped portion 152 of the power supply cable 150.

  The cylindrical base 162 further comprises a cylindrical inner housing 163 of axis coinciding with the axis of the cylindrical base 162 and opening on only one end of this base. This inner housing 163 has a diameter and a height substantially equal to the diameter and the height of the positive terminal 301 of the accumulator battery 300.

  The cylindrical base 162 is made of a conductive material such as steel but it internally comprises a non-conductive portion 164 disposed on the periphery of the housing 163, the open end of the housing 163 to near the bottom of this housing. Thus, the positive terminal 301 of the accumulator battery 300, to be electrically connected to the power supply cable 150, must be inserted to the bottom of the housing 163 of the covered terminal 160. The connection of other electrical cables intended to supply current to other electrical devices is then impossible to the extent that their fastening means would raise the covered terminal 160 relative to the positive terminal 301 of the accumulator battery 300, which would prevent the electrical contact between the positive terminal 301 and the covered terminal 160. These other electrical devices are therefore all connected downstream of the circuit breaker 1. The entire current delivered by the accumulator battery 300 therefore passes through the circuit breaker before being transmitted to electrical devices, which not only allows precise measurements of the in.ity of said current at the electrical input terminal. 100 of the circuit breaker 1, but also allows during a short circuit, to protect all the electrical devices by opening the contact means 3 of the circuit breaker 1.

  For fixing the covered terminal 160 to the positive terminal 301 of the accumulator battery 300, the cylindrical base 162 has a transverse groove 165 extending over its entire height, from its central axis to its outer wall. In addition, the cylindrical base 162 is pierced orthogonally to its transverse groove 165 of a through bore 166 which is threaded on one side of said groove 165. Thus, when a screw is inserted and then screwed into this opening bore 166, the two faces opposite the groove 165 are brought closer to each other so that the inside diameter of the housing 163 decreases. Thus, the positive terminal 301 of the accumulator battery 300 is clamped and then secured to the covered terminal 160. Advantageously, the entire device for breaking the current at the output of the accumulator battery 300 which comprises said battery, the cable power supply 150 and the circuit breaker 1 provided with its electrical input terminal 100 further comprises means for measuring the temperature of the power supply cable 150. These measurement means comprise in particular a temperature sensor 110 inserted into the stripped portion of the power supply cable 150 and then crimped together with the power supply cable 150 to ensure good thermal contact between the probe and the cable. This temperature sensor 110 is connected to the electronic card 10 of the circuit breaker 1 by means of an electric wire 111 running in the housing 10; of the electrical input terminal 100 and which leaves it through the lateral orifice 107 practiced close to the contacting element 102. Such a temperature probe 110 may consist of a resistive sensor of the CTN or CPT type comprising two wires in the same groove, including a stripped wire crimped with the power supply cable, and another possibly insulated wire connected to the electronic circuit breaker board. As a variant, this electric wire 111 may be coaxial with a central part intended to measure the temperature and an outer part intended to measure the electrical potential of the second stripped portion 152 of the electrical supply cable 150. Still advantageously, the electrical terminal of input 100 comprises means for measuring the voltage between two measuring points which correspond here to the two peripheral grooves 108.

  These means for measuring the voltage comprise the two electrical wires 113, 114 which each have an end wound around the electrical input terminal 100, at the bottom of one of the peripheral grooves 108, and another end connected to the electronic card 10 of the circuit breaker 1.

  These electrical wires are crimped into said peripheral grooves 108 and may, like the electrical wire 111 which connects the temperature probe 110 to the electronic card 10, enter the interior of the housing 1A via the oblique channels. 112. Alternatively, in order to simplify the fixing of the electrical wires 113, 114, the electric wire 114 which measures a first electrical potential on the electrical input terminal 100 may be replaced by the electric wire 111 if the latter is coaxial, and the electrical wire 113 which measures a second electrical potential may be replaced by an electrical wire connected to a lug held on the electrical input terminal 100 between the contactor element 102 and the housing 1A of the circuit breaker 1. in itself, these electrical wires 113, 114 each measure, independently of one another, an electric potential U1, U2 at two different measuring points. The difference in potential measured between the two peripheral grooves 108 determines the value of the voltage between these two barges. This potential difference is indeed non-zero insofar as the input electrical borie 100 has an internal resistance RO between the two peripheral grooves 108. As shown more particularly in FIGS. 6 and 7, the circuit breaker 1 comprises means for measuring the intensity of the current delivered by the accumulator battery 300 and passing through the electrical input terminal 100. These measuring means comprise the means for measuring the voltage between the two peripheral grooves 108 of the electrical terminal. input 100 and means for calculating the intensity of the current from said measured voltage. These calculation means comprise a subtractive operational amplifier 301, each of the two inputs is connected to one of the two electrical wires 113, 114. In a manner known per se, the subtractive operational amplifier 301 comprises an operational amplifier 302 powered for its current operation. and provided with two input terminals and one output terminal.

  The input terminals are connected to the electrical wires 1'3, 114 through resistors 303, 304 of the same value. The input terminal connected to the electric wire 114 is further connected to the electrical ground via a resistor 305. Furthermore, the input terminal connected to the electrical wire 113 is connected to the output terminal of the Operational amplifier 302 via a resistor 306 equal in value to the resistor 305 connected to the ground. The ratio between the value of this resistor 305 and that of the resistor 303 connected to the electrical wire 113 determines the gain K of the subtractive operational amplifier 301. Thus, the potential U3 of the output of the subtractive operational amplifier 301 corresponds to the product the gain K of the subtractive operational amplifier 301 and the potential difference measured between the two electrical wires 113, 114 according to the following formula: U3 = K. (U2-U1), K being the gain of the subtractive operational amplifier 301, U1 and U2 being respectively the potentials of the measurement wires 113, 114, and U3 being the potential of the output terminal of the subtractor operational amplifier 301. This output terminal is, in the circuit breaker electronic card 10 1, connected to an analog digital converter 310 which digitizes the potential U3 measured at the output of the subtractive operational amplifier 301 so that it can be exploited The microprocessor can then calculate the value of this intensity by performing the following calculation: I = U3: (K.RO), where I is the value of the intensity of the current passing through the terminal electrical input 100 and RO being the internal resistance of said electrical input terminal 100 between the two peripheral grooves 108. These measuring means are adapted to measure very low value voltages insofar as the gain K of the Operational amplifiertractor 301 may have a significant value. Moreover, they are also suitable for measuring small intensities since the input electrical terminal being hollow, it has a reduced section which increases its internal resistance which then becomes more easily measurable. Advantageously, the means for measuring the intensity of the current further comprise an electrical circuit 320 for calibrating the measurement chain of the intensity of the current passing through the electrical input terminal 1CO. This electrical circuit 320 is indeed useful insofar as, on the one hand, the subtractive operational amplifier 301 is not perfect so that the potential U3 measured on its output has an inherent error in the operation of the operational amplifier 302, and, on the other hand, it may appear variations of the value of the internal resistance RO of the electrical input terminal 100 between the two peripheral grooves 108. Indeed, the temperature variations and inaccuracy in the positioning electrical wires 113, 114 can vary substantially the value of this internal resistance RO.

  This electrical circuit 320 comprises in series a switch 321 and a resistor 322 of known value; it is connected, on one side, to an input of the subtractive operational amplifier 301, on the electrical wire 113 whose electrical potential is measured, and, on the other hand, to the electrical ground (identical to that on which is connected to the negative terminal of the accumulator battery 300). The switch 321 here is an electrical transistor. The resistor 322 has a value of 10 ohms which advantageously is at least ten times greater than the value of the internal resistance RO of the electrical input terminal 100 between the two peripheral grooves 108. This resistor 322 has a lower thermal sensitivity at 0.005% per degree so that differences in temperature have little effect on the measurement result. The method of measuring a precise value of the intensity of the current comprises different steps. During a first step, the switch 321 being open, the processor calculates with the aid of the above formulas an approximate value of the intensity of the current passing through the electrical input terminal 100. It also notes a first potential of the electric wire 113. Then, during a second step, it controls the closing of the switch 321. In a third step, it calculates again the intensity of the current pas:; ant between the two peripheral grooves 108 of the electrical input terminal. Part of the current passing through the electrical circuit 320, the result of the calculation is different. It also raises a second potential of the electrical wire 113. Finally, during a fourth and last step, knowing the exact value of the resistor 322 of the electrical circuit 320, it compares the two intensities calculated and the difference between the two potentials. measured on the electrical wire 113, and determines a refined value of the intensity of the current passing through the electrical input terminal. In such a way that the current variations due to the variations in the electrical requirements of the electrical equipment of the vehicle do not overcome the calculations, this closing of the switch 321 can be carried out regularly, for example every 50 milliseconds, so that the conditions between the first and third steps of the method be substantially identical. Another method making it possible to ensure that the calculations are not distorted consists in opening the contact means 3 before carrying out the measurement steps mentioned above. The electronic card 10 then keeps in memory in: storage means, for a given temperature measured by the temperature sensor 110, the correction value of the intensity of the current.

  Thus, subsequently, when the temperature measured by a temperature probe 110 has already been encountered, the electronic card 10 can determine by a simple calculation the refined value of the intensity of the current as a function, on the one hand, of the approximate value of the intensity of the current calculated by the subtractive operational amplifier 301, and, secondly, the correction value stored by the storage means. The use of the switch 321 is therefore reduced to cases where the temperature has not yet been encountered. The calibration of the measurement chain of the intensity of the current passing through the electrical input terminal 100 can then, thanks to these storage means, be implemented regularly and not continuously. According to an advantageous characteristic of the circuit breaker 1, its electrical output terminal 200, identical to its electrical input terminal 100, carries in one of its peripheral grooves an electrical wire 213 which, using a suitable device, 330 such as a voltmeter connected to an analog digital converter, to measure an electric potential at this point of the terminal. This electrical wire 213 is connected to the electronic card 10 which comprises means for comparing one of the potentials measured on the electrical input terminal 100 and the potential measured on the electrical output terminal 200.

  These comparison means, depending on the result of this comparison, can deduce, on the one hand, whether the contact bridge 3 is in the open or closed position, and, on the other hand, when the contact bridge 3 es`. in closed position, the state of wear of the contact means. Thus, if a significant potential difference characteristic of premature wear of the contact means is detected, the circuit breaker can inform the driver of the vehicle, for example by means of a light emitting diode disposed on the dashboard. of the vehicle. In the same way, the comparison means are adapted to detect micro-cuts of the current between the two electrical input and output terminals 200, said microcuts being characteristic of poor attachment of the power supply cable 150 to the battery. 300 or on the electrical input terminal 100. If it detects such micro-cuts, it can also inform the driver of the vehicle. Advantageously, the electronic circuit 10 also comprises means for calculating the internal resistance of the accumulator battery 300. These calculation means are located in the microprocessor of the battery switch 1; they are adapted to deduce, on the one hand, the variation, when the switch opens and closes, of the electric potential measured on one of the electric wires 113, 114, and, on the other hand, the value of the internal resistance of the power supply cable 150, the value of the internal resistance of the accumulator battery 300. The value and increase of this internal resistance indicating the remaining life of the accumulator battery 300 connected to the cutter circuit 1, the electronic circuit 10 can also provide the driver of the vehicle with an indication of the end of life of the accumulator battery 300.

  According to an advantageous characteristic of the invention, as shown more particularly in the diagram of FIG. 8, the electronic circuit 10 comprises means for determining at least one parameter value associated with the electric current flowing through the circuit breaker. 1 in function finely. These determination means comprise means for measuring at least one value of a quantity associated with said parameter. These measuring means may comprise either all means for measuring the current passing through the electrical input terminal 100 of the circuit breaker 1, or only the means for measuring the voltage between the two peripheral grooves 108 of the terminal. Said value of the magnitude may therefore be a voltage, an electric potential or an intensity. The determination means also comprise: calculation means which read the value of the quantity measured by the measuring means in order to determine the value of the parameter associated with said quantity. This parameter is chosen to be characteristic of a short circuit. This parameter may for example be an intensity, a voltage drop speed or a potential drop speed. The electronic card 10 also comprises means for storing at least one threshold value of at least one parameter associated with the electric current flowing through the circuit breaker. These threshold values are implemented during the manufacture of the electronic card 10 and therefore do not vary. They relate here to maximum values that the parameters determined by the determination means must not exceed.

  The threshold values may for example be, when the current is delivered by the accumulator battery 300 to power the electric motor 400 starting the main motor of the vehicle, 2000 amps, for 1 second, 1500 amps for 5 seconds, 1000 amps for 15 seconds, 500 amps for 60 seconds, and 0.1 volts per second.

  They may have different values when the current is delivered by the alternator 500 to recharge the accumulator battery 300. They can then be 200 amps for 1 seconds. These values are variable depending on the type of battery for which the circuit breaker 1 is intended.

  The electronic card 10 also comprises means for comparing the values determined by the determination means and threshold values associated with them. Here, these means compare in real time not only the value of the voltage drop speed with the threshold value associated with it, but also the intensity of the current flowing in the electrical terminal input 100 with the different values. threshold associated with it. Thus, as soon as at least one of the values of a parameter determined by the determination means exceeds the threshold value associated with it, the comparison means of the electronic card 10 provide information to processing means able to transform this parameter. information in an order to open the contact bridge 3. Therefore, as soon as a short circuit is detected by the circuit breaker 1, the latter quickly cuts the electrical contact at the output of the accumulator battery 300 so as to isolate it electrically to protect the accumulator battery 300 and the electrical apparatus it supplies or to protect the electric alternator 500 if the short circuit comes from the accumulator battery 300. Advantageously, the cutter circuit 1 comprises inside the housing 1A shock detection means and inclination detection means Elison. These detection means are sensors that are electrically connected to the electronic card 10 and send an electrical signal when they detect an impact greater for example 10 G or inclination of the upper housing for example 15 degrees. Such shock or inclination means that the vehicle provided with the circuit breaker 1 has suffered an accident, which increases the probability of a short circuit appears. In this case, the electronic card 10 is adapted to lowering the values of the set of threshold values (for example to 200 amperes for one second, whatever the direction of the current) so as to more effectively prevent the occurrence of any short circuit. . The present invention is not limited to the embodiments described and shown, but the skilled person will be able to make any variant within his mind.

Claims (11)

  1. A circuit breaker (1) comprising an electrical input terminal (100) intended to be connected to an accumulator battery (300), an electrical output terminal (200), contact means (3) adapted to closing or opening the electrical contact between the two electrical input (100) and output (200) terminals, and an electronic circuit (10) for controlling the contact means (3), characterized in that the electronic circuit ( 10) comprises means for storing at least one threshold value of at least one parameter associated with the electric current passing through the circuit breaker (1), means for determining at least one value of said circuit breaker parameter. (1) in operation, and means for comparing the value determined by the determination means (113, 114, 301) with said threshold value adapted to provide information to processing means able to transform this information into a control order. controlling contact means (3).   2. Circuit breaker (1) according to claim 1, characterized in that each threshold value of a parameter associated with the electric current flowing through the circuit breaker (1) depends on the direction of said current.   3. Circuit breaker (1) according to one of claims 1 and 2, characterized in that the determining means comprises measuring means (113, 114, 301) of at least one value of a magnitude associated with the electric current passing through one of the electrical input (100) or output (200) terminals of the circuit breaker (1).   4. Circuit breaker (1) according to claim 3, characterized in that the determining means (113, 114, 301) comprises calculation means which read the value of the quantity measured by the measuring means to find the value the parameter of the circuit breaker (1) in operation.   5. Circuit breaker (1) according to one of claims 3 and 4, characterized in that the electrical input terminal (100) or output (200) on which said measuring means (113, 114, 301) perform a measurement of the value of the magnitude associated with the electric current passing through this terminal (100) has a body (101) hollow.   6. Circuit breaker (1) according to one of claims 3 to 5, characterized in that one of the quantities whose value is measured by said means of measurement (113, 114, 301) is an electrical potential measured in one point (108) of one of the electrical input (100) or output (200) terminals.   7. A circuit breaker (1) according to claim 6, characterized in that said storage means stores threshold values of voltage drop speed.   8. Circuit breaker (1) according to claim 7, characterized in that said threshold threshold voltage drop threshold values are between 0.05 and 0.5 volts per second.   9. Circuit breaker (1) according to one of claims 1 to 8, characterized in that one of the magnitudes measured by said measuring means is the intensity (I) of the current flowing in the circuit breaker.   10. Circuit breaker (1) according to claim 9, characterized in that said storage means store threshold values of intensity of electric current associated with durations.   11. Circuit breaker (1) according to one of claims 11 to 10, characterized in that it comprises shock detection means and / or inclination adapted to lower the value of said threshold value when they detect shock and / or inclination.20