JP2006216516A - Power supply device for vehicle and adhesion detection method of power supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable to detect promptly adhesion of contactors after switching off an ignition switch. <P>SOLUTION: The power supply device of vehicle has a battery for driving 1 in which a plurality of battery units 2 are connected in series, a positive electrode contactor 3A and a negative electrode contactor 3B which are connected in series at the positive side and negative side of the battery for driving 1, and a detection circuit 4 which detects adhesion of the contact of the contactors 3. The detection circuit 4, in the state of controlling the positive electrode contactor 3A at switch-off, detects and compares the battery side voltage and the load side voltage of the positive electrode contactor 3A and when the voltage difference between the battery side voltage and the load side voltage is within an established range, judges that the positive electrode contactor 3A is in adhesion, further, in the state of controlling the negative electrode contactor 3B in switch-off, detects and compares the battery side voltage and the load side voltage of the negative electrode contactor 3B, and when the voltage difference between the battery side voltage and the load side voltage is within an established range, judges that the negative electrode contactor 3B is in adhesion. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power supply device that is mounted on a hybrid car, an electric vehicle, a fuel cell vehicle, and the like and supplies power to a motor that runs the vehicle.

  The power supply device for vehicles has a contactor connected to the output side. The contactor is switched on and off with the vehicle's ignition switch. When the ignition switch is turned on, the contactor is also turned on, and the power supply device can output to the motor. When the ignition switch is switched off, the contactor is switched off, disconnecting the output of the power supply from the load, preventing wasteful discharge of the battery, and improving safety.

Since the contactor has a very large current of several hundred A flowing through the load, the large current causes the welding of the contacts. Once the contactor contacts are welded, the output of the power supply cannot be cut off even if the ignition switch is turned off. In order to prevent this problem, an apparatus for detecting contactor welding has been developed. (See Patent Documents 1 to 4)
JP 2000-173428 A WO01 / 060652 JP 2000-270561 A JP 2004-14242 A

  As shown in FIG. 1, the power supply device described in Patent Documents 1 and 2 detects whether a current flows through a closed circuit including a contact of the contactor 33 and the battery 32 with a photocoupler 31. 33 welds are detected. When the contactor is welded, a current flows in the closed circuit via the contactor, and when the contactor is turned off, the current is interrupted and no current flows in the closed circuit. Therefore, the welding of the contactor is detected by detecting whether a current flows in the closed circuit.

  However, the power supply device having this circuit configuration has a drawback that it takes time to detect welding after the contactor is turned off, and the contactor welding cannot be detected promptly after the ignition switch is turned off. This is because a large-capacitance capacitor is connected to a load in a vehicle power supply device. The capacitor remains charged even after the contactor is turned off and disconnected from the power supply. A large-capacitance capacitor takes a considerable amount of time to discharge and reduce the voltage. When welding of the contactor is detected without discharging the capacitor, the photocoupler is energized from the capacitor even if the capacitor is not welded. For this reason, even if the contactor is normally switched off, the detection circuit erroneously determines that the contactor is welded. This adverse effect requires detecting contactor welding after the capacitor is sufficiently discharged and the photocoupler no longer detects current. However, since the capacitor connected to the load is extremely large, such as several thousand μF, it takes a very long time for the capacitor to be discharged and the voltage to drop. FIG. 2 shows a state where the voltage of the capacitor is lowered by switching the contactor off. As shown in this figure, the voltage of the capacitor takes about 600 msec for the voltage to decrease by 10%. Therefore, the detection circuit of FIG. 1 needs to detect contactor welding after switching the ignition switch off, waiting for a considerable time, fully discharging the capacitor, and detecting the contactor immediately. was there.

  The apparatus described in the gazette of patent document 3 detects the output voltage of the contactor of a positive electrode and a negative electrode, and determines welding of a contactor. This apparatus determines that the contactor on the off side is welded when a voltage is output from the contactor with one of the positive electrode and the negative electrode turned on and the other turned off. Since one contactor is turned on and the other is turned on, the voltage on the output side of the contactor becomes 0 V if the contactor is not welded.

  However, even in the device of this publication, when the ignition switch is turned off and the capacitor is not discharged, even if the contactor is not welded, a voltage appears on the output side of the contactor and erroneously detects. For this reason, after switching the ignition switch to OFF, it is necessary to detect the contactor welding after the capacitor is sufficiently discharged, and the welding cannot be detected promptly.

  Moreover, the apparatus of patent document 4 detects the electric current of the three-phase motor connected to a power supply device via an inverter, and determines welding of a contactor. When the positive and negative contactors are normally switched off, the power supply output is shut off. For this reason, none of the current of the three-phase motor flows. However, when the contactor is welded and power is supplied to the inverter, a current flows through the three-phase motor. For this reason, it is possible to detect the contact of the contactor by detecting the current of the three-phase motor. However, this device also supplies current to the inverter from a capacitor connected to the input side of the inverter after the ignition switch is turned off. For this reason, this apparatus also needs to detect the contactor welding after the capacitor is discharged, and cannot immediately detect the contactor welding after turning off the ignition switch.

The present invention has been developed for the purpose of solving such drawbacks. An important object of the present invention is to provide a power supply device for a vehicle that can quickly detect the contactor welding after the ignition switch is turned off.
Another important object of the present invention is to provide a power supply device for a vehicle that can accurately detect the welding of a contactor even if the power supply device is leaked.

The vehicle power supply device of the present invention has the following configuration in order to achieve the above-described object.
The power supply device for a vehicle according to claim 1 of the present invention is connected to a traveling battery 1 in which a plurality of battery units 2 are connected in series, and to the plus side and the minus side of the traveling battery 1 in series. A positive electrode contactor 3A, a negative electrode contactor 3B, and a detection circuit 4 that detects welding of the contact points of the contactor 3 are provided. The detection circuit 4 detects and compares the battery-side voltage and the load-side voltage of the positive contactor 3A in a state where the positive contactor 3A is turned off, and the voltage difference between the battery-side voltage and the load-side voltage is within the set range. In the state where the positive electrode contactor 3A is determined to be welded and the negative electrode contactor 3B is controlled to be turned off, the battery side voltage and the load side voltage of the negative electrode contactor 3B are detected and compared, and the battery side voltage and the load side voltage are compared. When the difference is within the set range, the negative electrode contactor 3B determines that welding has occurred.
Specifically, in the embodiment described later, the detection circuit 4 turns on the switch 15 connected to the plus side detection circuit 4A and turns off the switch 16 connected to the minus side detection circuit 4B. The battery side voltage and the load side voltage of the positive electrode contactor 3A are detected and compared, and if the voltage difference between the battery side voltage and the load side voltage is within the set range, the positive electrode contactor 3A is determined to be welded.
Further, the detection circuit 4 turns on the switch 16 connected to the minus side detection circuit 4B and turns off the switch 15 connected to the plus side detection circuit 4A, and the battery side voltage and the load side of the negative contactor 3B. The voltage is detected and compared, and when the voltage difference between the battery side voltage and the load side voltage is within the set range, the negative electrode contactor 3B determines that welding has occurred.

  In the vehicle power supply device according to claim 2 of the present invention, the detection circuit 4 is connected in parallel with the positive battery unit 2 connected to the positive contactor 3A in order to detect the battery side voltage of the positive contactor 3A. In order to connect the 1 resistance circuit 11 and detect the load side voltage of the positive contactor 3A, the second resistance circuit 12 is connected in parallel with the series circuit of the positive side battery unit 2 and the positive contactor 3A. In this power supply device, the first resistance circuit 11 detects the battery side voltage, the second resistance circuit 12 detects the load side voltage, compares the battery side voltage and the load side voltage, and detects the welding of the positive contactor 3A. To do.

  Furthermore, the power supply device for a vehicle according to claim 3 of the present invention is in parallel with the negative battery unit 2 connected to the negative contactor 3B so that the detection circuit 4 detects the battery side voltage of the negative contactor 3B. The fourth resistor circuit 14 is connected in parallel to the series circuit of the negative battery unit 2 and the negative electrode contactor 3B in order to connect the third resistor circuit 13 to the negative electrode contactor 3B. . In this power supply device, the third resistance circuit 13 detects the battery side voltage, the fourth resistance circuit 14 detects the load side voltage, compares the battery side voltage and the load side voltage, and detects the welding of the negative contactor 3B. To do.

  The power supply device for a vehicle according to the present invention includes a first resistor circuit 11, a second resistor circuit 12, a third resistor circuit 13, and a fourth resistor circuit 14 as a series circuit of a voltage dividing resistor 17 and a voltage detecting resistor 18. By detecting the voltage of the voltage detection resistor 18, the voltage of each resistor circuit can be detected.

  In the power supply device for a vehicle of the present invention, the second resistance circuit 12 can connect the positive electrode switch 15 in series with the resistor, and the fourth resistance circuit 14 can connect the negative electrode switch 16 in series with the resistor.

  In the power supply device for a vehicle according to the present invention, the voltage dividing resistor 17 of the first resistor circuit 11 and the voltage dividing resistor 17 of the second resistor circuit 12 have the same electric resistance, and the voltage detecting resistor 18 of the first resistor circuit 11 and the second resistor When the voltage detection resistor 18 of the resistor circuit 12 is the same electric resistance, and the voltage difference between the voltage detection resistor 18 of the first resistor circuit 11 and the voltage detection resistor 18 of the second resistor circuit 12 is within the set range, the positive contactor 3A can be determined as welding.

  In the vehicle power supply device according to the present invention, the voltage dividing resistor 17 of the third resistor circuit 13 and the voltage dividing resistor 17 of the fourth resistor circuit 14 have the same electric resistance, and the voltage detecting resistor 18 of the third resistor circuit 13 and the fourth resistor circuit 14 are the same. When the voltage detection resistor 18 of the resistor circuit 14 is the same electric resistance, and the voltage difference between the voltage detection resistor 18 of the third resistor circuit 13 and the voltage detection resistor 18 of the fourth resistor circuit 14 is within a set range, the negative contactor It can be determined that 3B is welded.

The welding detection method for a power supply device according to an eighth aspect of the present invention includes a positive contactor 3A and a negative contactor in which a plurality of battery units 2 are connected in series to a plus side and a minus side of a battery 1 for traveling. The detection circuit 4 detects 3B welding. In the welding detection method, in order to detect the battery side voltage of the positive contactor 3A with the detection circuit 4, the first resistance circuit 11 is connected in parallel with the positive side battery unit 2 connected to the positive contactor 3A. In order to detect the load side voltage of the positive contactor 3A, the second resistance circuit 12 is connected in parallel with the series circuit of the positive side battery unit 2 and the positive contactor 3A, and further the battery side voltage of the negative contactor 3B is determined. In order to detect, the third resistance circuit 13 is connected in parallel with the negative battery unit 2 connected to the negative contactor 3B, and the negative battery unit 2 is detected in order to detect the load side voltage of the negative contactor 3B. The 4th resistance circuit 14 is connected in parallel with the series circuit of 2 and the negative electrode contactor 3B. Further, the welding detection method includes a step of detecting and comparing the battery side voltage and the load side voltage of the contactor 3 in a state in which at least one contactor 3 is controlled to be off, and the voltage difference between the battery side voltage and the load side voltage. Is within the set range, the second resistor circuit 12 and the fourth resistor circuit 14 are energized, and the battery side voltage and the load side voltage of the one contactor 3 are detected and compared.
In this welding detection method, even if the voltage difference between the battery side voltage and the load side voltage is within the set range and it seems that welding has occurred, the voltage difference between the battery side voltage and the load side voltage due to electric leakage. May fall within the set range, so that erroneous detection of welding due to this leakage can be eliminated (corresponding to step (3) in the embodiment described later).
Specifically, in the embodiment described later, the battery side voltage and the load side voltage are detected in a state where the switch 15 and the switch 16 are simultaneously turned on and the second resistor circuit 12 and the fourth resistor circuit 14 are energized. By performing this, it is possible to eliminate erroneous detection due to the influence of electric leakage or the like.

The power supply device for a vehicle according to the present invention has an advantage that contactor welding can be detected promptly after the ignition switch is turned off. The power supply device for a vehicle of the present invention detects and compares the battery side voltage and the load side voltage of the positive contactor in a state where the positive contactor is turned off, and the voltage difference between the battery side voltage and the load side voltage is If it is within the set range, the positive electrode contactor determines that welding has occurred, and further, the battery side voltage and load side voltage of the negative electrode contactor are detected and compared while the negative electrode contactor is controlled to be off. This is because the negative electrode contactor determines that welding occurs when the voltage difference is within the set range.
Specifically, in the embodiments described later, the battery side voltage and the load side of the positive contactor are turned on while the switch connected to the plus side detection circuit is turned on and the switch connected to the minus side detection circuit is turned off. When the voltage difference between the battery-side voltage and the load-side voltage is within the set range, the positive contactor determines that welding has occurred and turns on the switch connected to the minus-side detection circuit. With the switch connected to the side detection circuit turned off, the battery side voltage and the load side voltage of the negative contactor are detected and compared, and if the voltage difference between the battery side voltage and the load side voltage is within the set range, the negative contactor Is determined to be welded.
The power supply device with this structure eliminates the influence of the load on the vehicle, and in the ON state where the contactor is welded, the battery side voltage and the load side voltage are the same voltage, so the voltage difference between the battery side voltage and the load side voltage is detected. Thus, contactor welding can be detected accurately and promptly.

  Furthermore, the welding detection method according to claim 8 of the present invention has a feature that can prevent erroneous detection due to electric leakage. The welding detection method of the present invention detects the voltage difference between the battery side voltage and the load side voltage of at least one contactor, and if this voltage difference is within a set range, the second resistance circuit and the fourth resistance circuit This is because the battery side voltage and the load side voltage of the contactor are detected and compared to detect welding. Even if the detected voltage difference between the battery-side voltage and the load-side voltage is within the setting range and welding appears to have occurred, the voltage difference between the battery-side voltage and the load-side voltage due to electrical leakage is within the setting range. However, in the present invention, when the voltage difference is within the set range, the second resistance circuit and the fourth resistance circuit are energized to detect and compare the battery side voltage and the load side voltage. Therefore, it is possible to reliably prevent erroneous detection of welding due to electric leakage.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment described below exemplifies a power supply device for a vehicle and a welding detection method for the power supply device for embodying the technical idea of the present invention, and the present invention includes a power supply device and a welding detection method. Not specified below.

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The vehicle power supply device shown in FIG. 3 is mounted on a hybrid car, mounted on an electric vehicle, or mounted on a fuel cell vehicle, and drives a motor connected as a load to drive the vehicle. The power supply device of this figure is connected in series to a traveling battery 1 in which a plurality of battery units 2 are connected in series, and a plus side and a minus side of the traveling battery 1 to supply power to a load 20. A positive electrode contactor 3A, a negative electrode contactor 3B, and a detection circuit 4 that detects welding of the contact points of the contactor 3 are provided. The load 20 is the motor described above, and as shown in the figure, the equivalent circuit of the electric circuit includes a capacitor component and a resistance component.

  The load 20 has a large-capacity capacitor 21 connected in parallel. The capacitor 21 supplies power to the load 20 together with the traveling battery 1 in a state where the contact of the contactor 3 is switched on. In particular, the capacitor 21 instantaneously supplies large power to the load 20. The instantaneous power that can be supplied to the load 20 can be increased by connecting the capacitor 21 in parallel to the traveling battery 1. Since the electric power that can be supplied from the capacitor 21 to the load 20 is proportional to the capacitance, a capacitor having an extremely large capacitance of, for example, 4000 to 6000 μF is used.

  The traveling battery 1 has four battery units 2 connected in series. The battery unit 2 has a plurality of battery modules connected in series. In the battery module, a plurality of secondary batteries are linearly connected in series. The secondary battery is a nickel metal hydride battery or a lithium ion secondary battery. The battery module has 5 to 6 secondary batteries connected in series. However, the battery module can also connect 4 or less, or 7 or more secondary batteries in series. A traveling battery 1 including four battery units 2 has 7 to 8 battery modules connected in series to each battery unit 2.

  The traveling battery 1 has an output voltage as high as 200 to 400 V, for example, so that large electric power can be supplied to the motor. However, the power supply device can also connect a DC / DC converter (not shown) to the output side of the traveling battery 1 to boost the voltage of the traveling battery 1 and supply power to the load 20. This power supply device can reduce the output voltage of the battery for traveling by reducing the number of secondary batteries connected in series. Therefore, the traveling battery 1 can have an output voltage of 150 to 400 V, for example.

In the power supply device of the present invention, the battery unit 2 is not necessarily configured by a battery module, and unit cells can be connected in series to form a battery unit. Moreover, the battery for driving | running | working does not necessarily need to be comprised with 4 sets of battery units.
For reference, the current supplied from the traveling battery 1 is measured by a current sensor (not shown) connected in series, and the voltage of each battery unit 2 is measured by the voltage across the battery unit 2. Can be obtained. And about abnormality of a current sensor, when the change of an electric current is small with respect to the change of the voltage of each voltage unit 2 or the battery 1 for driving | running | working, abnormality of a current sensor can be detected. Here, the measurement timing of the current and various voltages slightly deviates, but if the comparison is made with values measured within a predetermined period, the abnormality of the current sensor can be detected as described above.

  The positive contactor 3A is connected between the positive electrode side of the traveling battery 1 and the positive output terminal, and the negative contactor 3B is connected between the negative electrode side of the traveling battery 1 and the negative output terminal. The positive electrode contactor 3A and the negative electrode contactor 3B have excitation coils for controlling the contacts on and off. The positive electrode contactor 3A and the negative electrode contactor 3B are relays each having an exciting coil so that each can be controlled on and off independently. The positive electrode contactor 3A and the negative electrode contactor 3B are switched on when the contact is turned on and the current supply is stopped while the exciting coil is energized.

  When the ignition switch is turned on, the power supply device holds the positive electrode contactor 3A off and switches the negative electrode contactor 3B on. In this state, the precharge circuit (FIG. 3) is connected in parallel with the positive electrode contactor 3A. The capacitor 21 is pre-charged with (not shown). After the capacitor 21 is precharged, the positive electrode contactor 3A is switched from OFF to ON, and the traveling battery 1 is connected to the load 20. Thereafter, the precharge relay of the precharge circuit is switched off.

  When the ignition switch of the vehicle is switched off, the energization of the excitation coils of the positive contactor 3A and the negative contactor 3B is cut off. The positive electrode contactor 3A and the negative electrode contactor 3B in which the energization of the exciting coil is cut off are switched off when operating normally. However, when the contact is welded, it is not switched off but kept on.

  The detection circuit 4 turns off the ignition switch, cuts off the energization of the exciting coils of the positive contactor 3A and the negative contactor 3B, controls both of them to the off state, and detects whether or not it has been normally switched off.

The detection circuit 4 detects the welding of the contactor 3 on the following operation principle.
[Detection of welding of positive contactor 3A]
The battery side voltage and the load side voltage of the positive contactor 3A are detected and compared in a state where the positive contactor 3A is controlled to be turned off, that is, in a state where the energization of the exciting coil of the positive contactor 3A is cut off. When the positive electrode contactor 3A is welded and in the on state, the voltage difference between the battery side voltage and the load side voltage becomes the same voltage. Therefore, when the voltage difference between the battery side voltage and the load side voltage is within the set range, it is determined that the positive electrode contactor 3A is welded.

“Detection of welding of negative electrode contactor 3B”
The negative electrode contactor 3B also detects welding on the same operating principle. That is, the battery side voltage and the load side voltage of the negative contactor 3B are detected and compared in a state in which the negative contactor 3B is controlled to be turned off, that is, in a state where the energization of the exciting coil of the negative contactor 3B is cut off. When the negative electrode contactor 3B is welded and in the on state, the voltage difference between the battery side voltage and the load side voltage becomes the same voltage. Therefore, when the voltage difference between the battery side voltage and the load side voltage is within the set range, it is determined that the negative electrode contactor 3B is welded.

  As described above, the power supply device of the present invention detects the battery-side voltage and the load-side voltage of the contactor 3, and determines that welding occurs when both voltages are the same voltage. This is because when the contactor 3 is welded, the battery side voltage and the load side voltage become the same voltage. The battery side voltage and the load side voltage can also be measured by detecting the current flowing through the resistor. Since the product of the electrical resistance and the current becomes a voltage, detecting the current of the resistor whose electrical resistance is specified is substantially equivalent to detecting the voltage. Further, as shown in the figure, the battery side voltage and the load side voltage can be detected by dividing with a resistor, but can also be detected without dividing. Furthermore, the current can also be detected by shunting with a resistor. Therefore, instead of directly detecting the battery side voltage and the load side voltage, the power supply device of the present invention detects the current of the resistor by connecting a resistor to the voltage detecting portion, or the voltage is divided by a resistor. It is possible to detect and compare the battery side voltage and the load side voltage indirectly by dividing and detecting the resistance ratio at 17.

  Furthermore, the power supply device detection circuit 4 of the present invention is preferably arranged in parallel with the positive battery unit 2 connected to the positive contactor 3A, as shown in the figure, in order to detect the welding of the positive contactor 3A. In order to connect the 1 resistance circuit 11 and detect the load side voltage of the positive contactor 3A, the second resistance circuit 12 is connected in parallel with the series circuit of the positive side battery unit 2 and the positive contactor 3A. In the detection circuit 4, the first resistance circuit 11 detects the battery side voltage, and the second resistance circuit 12 detects the load side voltage. The detected battery side voltage and the load side voltage are compared, and welding of the positive electrode contactor 3A is detected.

  In addition, the detection circuit 4 connects the third resistance circuit in parallel with the negative battery unit 2 connected to the negative contactor 3B in order to detect the battery side voltage of the negative contactor 3B, and loads the negative contactor 3B. In order to detect the side voltage, the fourth resistance circuit 14 is connected in parallel with the series circuit of the negative battery unit 2 and the negative contactor 3B. In the detection circuit 4, the third resistance circuit 13 detects the battery side voltage, and the fourth resistance circuit 14 detects the load side voltage. The battery side voltage and the load side voltage are compared, and welding of the negative electrode contactor 3B is detected.

  Furthermore, in the illustrated detection circuit 4, a positive switch 15 is connected to the second resistor circuit 12 in series with the resistor, and a negative switch 16 is connected to the fourth resistor circuit 14 in series with the resistor. When detecting the welding of the positive contactor 3A, the detection circuit 4 turns on the positive switch 15 and turns off the negative switch 16 to detect and compare the battery side voltage and the load side voltage. When detecting the welding of the negative electrode contactor 3B, the negative electrode switch 16 is turned on and the positive electrode switch 15 is turned off to detect and compare the battery side voltage and the load side voltage. Although not shown, in the resistance circuits 11 and 13, a switch to be energized can be inserted in series only when the voltage generated in the voltage detection resistor 18 is measured under the control of the control circuit 10.

  The detection circuit 4 having this circuit configuration is characterized in that after the ignition switch is switched off, the influence of the capacitor 21 connected to the load 20 is eliminated and the welding of the contactor 3 can be detected promptly. First, after the positive electrode contactor 3A and the negative electrode contactor 3B are turned off, when detecting the welding of the positive electrode contactor 3A, the switch 15 is turned on, the switch 16 is turned off, and the third resistor circuit 13 and the fourth resistor circuit 14 are included. When the minus side detection circuit 4B is disconnected from the load side, the voltages of the first resistance circuit 11 and the second resistance circuit 12 can be detected, and when the welding of the negative contactor 3B is detected, the first resistance circuit 11 and the second resistance circuit This is because the voltage of the third resistor circuit 13 and the fourth resistor circuit 14 can be detected by separating the plus side detection circuit 4A including the circuit 12 from the load side. By disconnecting the minus side detection circuit 4B or the plus side detection circuit 4A from the load side and detecting the voltage of the resistance circuit, it is possible to eliminate the influence of the voltage charged in the capacitor 21 and accurately detect the voltage of the resistance circuit. .

Further, the first to fourth resistance circuits 11, 12, 13, and 14 in the figure connect a voltage dividing resistor 17 and a voltage detecting resistor 18 in series to divide and detect the battery side voltage and the load side voltage. And a resistance circuit. This resistance circuit detects a voltage by dividing it into a resistance ratio. Since the battery side voltage and the load side voltage are high voltages, the resistance circuit that divides the voltage in this way has a feature that the detection voltage can be lowered. A resistor circuit composed of a series circuit of a voltage dividing resistor 17 and a voltage detecting resistor 18 is configured such that a battery side voltage or a load side voltage is expressed by assuming that the resistance value of the voltage dividing resistor 17 is Rb and the resistance value of the voltage detecting resistor 18 is Ra.
The voltage is divided into Ra / (Ra + Rb) and output to both ends of the voltage detection resistor 18.

  In the detection circuit 4, the voltage dividing resistor 17 of the first resistor circuit 11 and the voltage dividing resistor 17 of the second resistor circuit 12 are set to the same electric resistance, and the voltage detecting resistor 18 of the first resistor circuit 11 and the second resistor circuit 12 The voltage detection resistor 18 has the same electrical resistance. The detection circuit 4 can make the first resistor circuit 11 and the second resistor circuit 12 have the same voltage dividing ratio. Therefore, when the battery side voltage and the load side voltage of the positive contactor 3A are the same voltage, the voltages of the battery side voltages of the first resistance circuit 11 and the second resistance circuit 12 are also equal. For this reason, when the voltage of the voltage detection resistor 18 of the 1st resistance circuit 11 and the 2nd resistance circuit 12 is equal, ie, when it exists in a setting range, it can determine with positive electrode contactor 3A welding.

  In the detection circuit 4, the voltage dividing resistor 17 of the third resistor circuit 13 and the voltage dividing resistor 17 of the fourth resistor circuit 14 have the same electric resistance, and the voltage detecting resistor 18 of the third resistor circuit 13 and the fourth resistor circuit 14 voltage detection resistors 18 have the same electrical resistance. The detection circuit 4 can make the third resistor circuit 13 and the fourth resistor circuit 14 have the same voltage dividing ratio. Therefore, when the battery side voltage and the load side voltage of the negative contactor 3B are the same voltage, the voltage of the battery side voltage of the third resistance circuit 13 and the fourth resistance circuit 14 is also equal. For this reason, when the voltage of the voltage detection resistor 18 of the 3rd resistance circuit 13 and the 4th resistance circuit 14 is equal, ie, when it exists in a setting range, it can determine with the negative electrode contactor 3B welding.

  Preferably, the first resistor circuit 11, the second resistor circuit 12, the third resistor circuit 13, and the fourth resistor circuit 14 have the same electrical resistance of the voltage dividing resistor 17, and the same electrical resistance of the voltage detection resistor 18. To do.

  In order to detect the welding of the contactor 3 by comparing the battery side voltage and the load side voltage, the detection circuit 4 in the figure determines the welding of the contactor 3 from the voltage comparison unit 19 and the signal output from the comparison unit 19. The control circuit 10 is provided. The comparison unit 19 is a differential amplifier. However, the comparison unit is not necessarily a differential amplifier. For example, the voltage of the voltage detection resistor is converted into a digital signal by an A / D converter, the digital signal is input to the control circuit, and the control circuit compares the input voltage to determine the contactor welding.

  The control circuit 10 compares input voltages to determine whether the contactor 3 is welded, and further controls the positive electrode switch 15 and the negative electrode switch 16 to be turned on and off when the welding is detected.

The control circuit 10 detects the welding of the positive contactor 3A and the negative contactor 3B in the following steps. However, in the following, the voltage detection resistors 18 in the first, second, third, and fourth resistance circuits 11, 12, 13, and 14 are referred to as the first, second, third, and fourth voltage detection resistors 18, respectively. To do.
First, when the ignition switch is switched off, the energization of the exciting coils of the positive contactor 3A and the negative contactor 3B is cut off.

A. Determination of welding of the positive contactor 3A (1) When the ignition switch is turned off, the control circuit 10 waits for a certain time, for example, 50 msec, to turn on the positive switch 15 and turn off the negative switch 16 . In this state, the voltages of the first voltage detection resistor 18 of the first resistor circuit 11 and the second voltage detection resistor 18 of the second resistor circuit 12 are detected and compared.
(2) When the voltage difference between the first voltage detection resistor 18 and the second voltage detection resistor 18 is not within a set range (for example, within 10% of the voltage of the first voltage detection resistor 18), the control circuit 10 It is determined that 3A is not welded. That is, if not completely welded, no current flows through the second resistor circuit 12, so that the voltage generated in the second voltage detection resistor 18 is zero, and the first voltage detection resistor of the first resistor circuit 11. The voltage generated at 18 is different.
Here, except when there is a leakage described below, when there is welding, the first resistance circuit 11 and the second resistance circuit 12 are connected in parallel, so the first voltage detection resistor 18 and the second voltage detection resistor The voltage generated at 18 is the same. Therefore, it is possible to determine whether or not the positive electrode contactor 3A is welded in steps (1) and (2) without adopting the following step (3).
(3) When the voltage difference between the first voltage detection resistor 18 of the first resistor circuit 11 and the second voltage detection resistor 18 of the second resistor circuit 12 is within a set range (hereinafter referred to as the same voltage), the control circuit 10 Both the positive switch 15 and the negative switch 16 are turned on. In this state, the voltages of the first voltage detection resistor 18 and the second voltage detection resistor 18 are again detected and compared. Even if the voltages of the first voltage detection resistor 18 and the second voltage detection resistor 18 are within the set range, the positive contactor 3A is not immediately determined to be welded, as will be described below. This is because both voltages may fall within the set range.
For example, when the middle point of the traveling battery 1 is leaked and the leakage resistance is connected to the ground line, a current flows through the second resistance circuit 12 as shown in FIG. At this time, a current flows through the second resistance circuit 12 with the voltage charged in the capacitor 21. Due to this current, the same voltage as the first voltage detection resistor 18 is generated in the second voltage detection resistor 18 of the second resistance circuit 12, and the positive contactor 3A may be erroneously determined to be welded. In order to avoid this problem, when the negative switch 16 is turned on in addition to the positive switch 15, a current flows through a path different from that shown in FIG. 4 as shown in FIG. Accordingly, the value of the current flowing through the second resistance circuit 12 changes. For this reason, even if only the positive switch 15 is turned on and the voltage of the second voltage detection resistor 18 of the second resistor circuit 12 is equal to the voltage of the first voltage detection resistor 18 of the first resistor circuit 11, the negative electrode When the switch 16 is turned on and the current value changes, the voltage of the second voltage detection resistor 18 of the second resistance circuit 12 changes and becomes a voltage different from that of the first voltage detection resistor 18 of the first resistance circuit 11. Therefore, when only the positive switch 15 is turned on and the first voltage detection resistor 18 of the first resistance circuit 11 and the second voltage detection resistor 18 of the second resistance circuit 12 have the same voltage, the negative switch 16 is also turned on. If the two voltages are different from each other, it is determined that the positive electrode contactor 3A is not welded. When the positive electrode contactor 3A is welded, the first voltage detection resistor 18 of the first resistor circuit 11 can be used regardless of whether only the positive electrode switch 15 is turned on or both the positive electrode switch 15 and the negative electrode switch 16 are turned on. This is because the voltage induced in the second voltage detection resistor 18 of the second resistance circuit 12 becomes the same voltage.
When the positive electrode contactor 3A is not welded and is normal and both the positive electrode switch 15 and the negative electrode switch 16 are turned on, current flows from the capacitor 21 and current flows to the second voltage detection resistor 18. A voltage may be generated, resulting in the same voltage as the voltage of the first voltage detection resistor 18, and may be erroneously detected as a welded state. Therefore, in the present embodiment, except for the case where the leakage occurs as shown in FIG. 4 as described above, both the positive switch 15 and the negative switch 16 are not turned on but are alternately turned on.

B. Determination of welding of negative electrode contactor 3B (1) After determining the welding of positive electrode contactor 3A, control circuit 10 turns negative electrode switch 16 on and positive electrode switch 15 off. In this state, the voltages of the third voltage detection resistor 18 of the third resistor circuit 13 and the fourth voltage detection resistor 18 of the fourth resistor circuit 14 are detected and compared.
(2) When the voltage difference between the third voltage detection resistor 18 and the fourth voltage detection resistor 18 is not within the set range (for example, within 10% of the voltage of the third voltage detection resistor 18), the control circuit 10 It is determined that 3B is not welded.
Here, except when there is a leakage as described below, when there is welding, the third resistor circuit 13 and the fourth resistor circuit 14 are connected in parallel, so the third voltage detection resistor 18 and the fourth voltage detection resistor. The voltage generated at 18 is the same. Therefore, it is possible to determine whether or not the negative electrode contactor 3B is welded in the steps (1) and (2) without adopting the following step (3).
(3) When the voltage difference between the third voltage detection resistor 18 of the third resistor circuit 13 and the fourth voltage detection resistor 18 of the fourth resistor circuit 14 is within the set range (hereinafter referred to as the same voltage), the control circuit 10 Both the positive switch 15 and the negative switch 16 are turned on. In this state, the voltages of the third voltage detection resistor 18 and the fourth voltage detection resistor 18 are again detected and compared. Even when the voltages of the third voltage detection resistor 18 and the fourth voltage detection resistor 18 are within the set range, the negative battery contactor 3B is not immediately determined to be welded, as in the case of the positive electrode contactor 3A. This is because electric leakage may cause both voltages to fall within the set range.
For example, as in the case of the positive contactor 3 </ b> A, when the middle point of the traveling battery 1 leaks and the leakage resistance is connected to the ground line, a current flows through the fourth resistance circuit 14. At this time, a current flows through the fourth resistance circuit 14 with the voltage charged in the capacitor 21. Due to this current, the same voltage as the third voltage detection resistor 18 may be generated in the fourth voltage detection resistor 18 of the fourth resistance circuit 14, and the negative contactor 3B may be erroneously determined to be welded. In order to avoid this problem, when the positive switch 15 is turned on in addition to the negative switch 16, current flows through different paths. Accordingly, the value of the current flowing through the fourth resistance circuit 14 changes. For this reason, even when only the negative switch 16 is turned on, the voltage of the fourth voltage detection resistor 18 of the fourth resistance circuit 14 is equal to the voltage of the third voltage detection resistor 18 of the third resistance circuit 13. When the switch 15 is turned on and the current value changes, the voltage of the fourth voltage detection resistor 18 of the fourth resistance circuit 14 changes and becomes a voltage different from that of the third voltage detection resistor 18 of the third resistance circuit 13. Therefore, when only the negative switch 16 is turned on and the third voltage detection resistor 18 of the third resistor circuit 13 and the fourth voltage detection resistor 18 of the fourth resistor circuit 14 have the same voltage, the positive switch 15 is also turned on. If the two voltages are different from each other, it is determined that the negative electrode contactor 3B is not welded. When the negative electrode contactor 3B is welded, the third voltage detection resistor 18 of the third resistor circuit 13 is turned on regardless of whether only the negative electrode switch 16 is turned on or both the negative electrode switch 16 and the positive electrode switch 15 are turned on. This is because the voltage induced in the fourth voltage detection resistor 18 of the fourth resistance circuit 14 is the same voltage.

It is a circuit diagram of the conventional power supply device. It is a graph which shows the state in which a capacitor | condenser is discharged and a voltage falls. It is a circuit diagram of the power supply device for vehicles concerning one example of the present invention. It is a circuit diagram which shows the state in which the power supply device shown in FIG. 3 leaks. It is a circuit diagram which shows the state which turns on the negative electrode switch of the power supply device shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Battery for driving | running | working 2 ... Battery unit 3 ... Contactor 3A ... Positive electrode contactor
3B ... Negative contactor 4 ... Detection circuit 4A ... Positive detection circuit
4B ... Negative side detection circuit 10 ... Control circuit 11 ... First resistor circuit 12 ... Second resistor circuit 13 ... Third resistor circuit 14 ... Fourth resistor circuit 15 ... Positive electrode switch 16 ... Negative electrode switch 17 ... Voltage dividing resistor 18 ... Voltage Detection resistor 19: Comparison unit 20 ... Load 21 ... Capacitor 31 ... Photocoupler 32 ... Battery 33 ... Contactor

Claims (8)

A traveling battery (1) in which a plurality of battery units (2) are connected in series, and a positive contactor (3A) and a negative contactor connected in series on the positive side and the negative side of the traveling battery (1) (3B) and a power supply device comprising a detection circuit (4) for detecting contact welding of the contactor (3),
The detection circuit (4) detects and compares the battery side voltage and the load side voltage of the positive contactor (3A) with the positive contactor (3A) turned off, and compares the voltage difference between the battery side voltage and the load side voltage. Is within the set range, the positive electrode contactor (3A) determines welding,
Furthermore, with the negative contactor (3B) controlled to be off, the battery side voltage and the load side voltage of the negative contactor (3B) are detected and compared, and the voltage difference between the battery side voltage and the load side voltage is within the set range. If there exists, the power supply device for vehicles which a negative electrode contactor (3B) will judge as welding. In order for the detection circuit (4) to detect the battery side voltage of the positive contactor (3A), the first resistance circuit (11) is connected in parallel with the positive battery unit (2) connected to the positive contactor (3A). In order to detect the load side voltage of the positive contactor (3A), connect the second resistance circuit (12) in parallel with the series circuit of the positive battery unit (2) and the positive contactor (3A). And
The first resistor circuit (11) detects the battery side voltage, the second resistor circuit (12) detects the load side voltage, compares the battery side voltage with the load side voltage, and welds the positive contactor (3A). The power supply device for vehicles described in Claim 1 to detect. In order for the detection circuit (4) to detect the battery side voltage of the negative contactor (3B), a third resistance circuit is connected in parallel with the negative battery unit (2) connected to the negative contactor (3B). In order to detect the load side voltage of the negative contactor (3B), the fourth resistance circuit (14) is connected in parallel with the series circuit of the negative battery unit (2) and the negative contactor (3B).
The third resistor circuit (13) detects the battery side voltage, the fourth resistor circuit (14) detects the load side voltage, compares the battery side voltage with the load side voltage, and welds the negative contactor (3B). The power supply device for vehicles described in Claim 1 to detect.   The first resistor circuit (11), the second resistor circuit (12), the third resistor circuit (13), and the fourth resistor circuit (14) are divided into a voltage dividing resistor (17) and a voltage detecting resistor (18). 4. The vehicle power supply device according to claim 2, wherein the voltage of the first to fourth resistance circuits is detected by detecting the voltage of the voltage detection resistor (18) in the series circuit of the above.   The second resistor circuit (12) has a positive switch (15) connected in series with the resistor, and the fourth resistor circuit (14) has a negative switch (16) connected in series with the resistor. And a power supply device for a vehicle described in 3. The voltage dividing resistor (17) of the first resistor circuit (11) and the voltage dividing resistor (17) of the second resistor circuit (12) have the same electrical resistance.
The voltage detection resistor (18) of the first resistor circuit (11) and the voltage detection resistor (18) of the second resistor circuit (12) have the same electrical resistance,
When the voltage difference between the voltage detection resistor (18) of the first resistor circuit (11) and the voltage detection resistor (18) of the second resistor circuit (12) is within the set range, the positive contactor (3A) is welded. The power supply device for vehicles according to claim 4 which judges. The voltage dividing resistor (17) of the third resistor circuit (13) and the voltage dividing resistor (17) of the fourth resistor circuit (14) have the same electrical resistance.
The voltage detection resistor (18) of the third resistor circuit (13) and the voltage detection resistor (18) of the fourth resistor circuit (14) have the same electrical resistance,
If the voltage difference between the voltage detection resistor (18) of the third resistor circuit (13) and the voltage detection resistor (18) of the fourth resistor circuit (14) is within the set range, the negative contactor (3B) is welded. The power supply device for vehicles according to claim 4 which judges. Detection circuit for welding of positive contactor (3A) and negative contactor (3B) connected in series on the positive side and negative side of battery (1) for traveling, in which a plurality of battery units (2) are connected in series ( A method for detecting welding of a power supply device detected in 4),
In order to detect the battery side voltage of the positive contactor (3A) with the detection circuit (4), the first resistance circuit (11) is connected in parallel with the positive side battery unit (2) connected to the positive contactor (3A). ) To detect the load side voltage of the positive contactor (3A), the second resistance circuit (12) is connected in parallel with the series circuit of the positive battery unit (2) and the positive contactor (3A). connection,
In order to detect the battery side voltage of the negative contactor (3B), a third resistor circuit (13) is connected in parallel with the negative battery unit (2) connected to the negative contactor (3B). In order to detect the load side voltage of (3B), a fourth resistance circuit (14) is connected in parallel with the series circuit of the negative battery unit (2) and the negative contactor (3B),
In a state in which at least one contactor (3) is controlled to be turned off, a step of detecting and comparing a battery side voltage and a load side voltage of the contactor (3);
When the voltage difference between the battery side voltage and the load side voltage is within the set range, the second resistance circuit (12) and the fourth resistance circuit (14) are energized, and the battery side voltage of the one contactor (3) And a step of detecting and comparing a load side voltage.

Images