JP6742191B2 - Sticking detection device and battery system - Google Patents

Description

The present invention relates to a sticking detection device and a battery system.

2. Description of the Related Art Conventionally, vehicles such as hybrid vehicles and electric vehicles have a secondary battery as a power source for supplying electric power to a motor or the like which is a power source. The secondary battery supplies electric power to a motor connected via a plurality of relays.

Even if the relays are controlled from the ON state to the OFF state, an abnormality may occur in which the relays are stuck in the ON state. When the relay sticks, the resistance value of the insulation resistance connected to the secondary battery fluctuates. Therefore, a system is known in which the fixation of the relay is determined by detecting such a variation in the insulation resistance by applying an AC signal to the secondary battery. (For example, refer to Patent Document 1).

JP, 2005-79730, A

However, although the above-mentioned system can determine whether or not a plurality of relays are stuck, it does not specify the relay sticking point and cannot individually detect the stuck state of each relay.

The present invention has been made in view of the above, and an object of the present invention is to provide a sticking detection device and a battery system capable of detecting the stuck state of each relay.

In order to solve the above problems and achieve the object, a sticking detection device of the present invention includes a voltage detection unit and a sticking detection unit. The voltage detection unit is connected to one pole of the secondary battery via a coupling capacitor, and detects a change in voltage of an insulation resistance provided between the one pole of the secondary battery and the ground. The sticking detection unit detects the voltage by discharging a capacitor connected between the other ends of the plurality of relays in a state in which a plurality of relays, one end of which is connected to each of both electrodes of the secondary battery, is controlled to be off. The stuck states of the plurality of relays are respectively detected according to the fluctuations in the voltage detected by the section.

According to the present invention, the stuck state of each relay can be detected.

FIG. 1 is a diagram showing a configuration of a battery system according to an embodiment. FIG. 2 is a graph showing the voltage at point A when a pulse signal is applied to the battery system according to the embodiment. FIG. 3A is a diagram showing an equivalent circuit when the relay according to the embodiment is fixed. FIG. 3B is a diagram showing an equivalent circuit when the relay according to the embodiment is not fixed. FIG. 4A is a diagram showing an equivalent circuit of the battery system before discharging the capacitor when the relay according to the embodiment is fixed. FIG. 4B is a diagram showing an equivalent circuit of the battery system after the capacitor is discharged when the relay according to the embodiment is fixed. FIG. 5 is a graph showing voltage fluctuations at point A detected by the voltage detection unit according to the embodiment. FIG. 6A is a diagram showing an equivalent circuit of the battery system before discharging the capacitor when the relay according to the embodiment is fixed. FIG. 6B is a diagram showing an equivalent circuit of the battery system after the capacitor is discharged when the relay according to the embodiment is fixed. FIG. 7 is a diagram showing an equivalent circuit of the battery system when both of the relays according to the embodiment are fixed. FIG. 8 is a flowchart showing the abnormality detection processing according to this embodiment. FIG. 9 is a flowchart showing the sticking determination processing according to this embodiment. FIG. 10 is a flowchart showing the sticking detection processing according to this embodiment. FIG. 11 is a diagram showing a configuration of a battery system according to a modified example of the embodiment. FIG. 12 is a graph showing the voltage at point A when a high-frequency pulse signal is applied to the battery system according to this embodiment.

Hereinafter, embodiments of a sticking detection device and a battery system disclosed in the present application will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments described below.

FIG. 1 is a diagram showing a configuration of a battery system S according to the present embodiment. The battery system shown in FIG. 1 is used, for example, as a vehicle power source for electric vehicles and hybrid vehicles.

The battery system S includes a secondary battery 1, a plurality of relays SMR-B and SMR-G, a capacitor 2, insulation resistances 31 to 34, and a sticking detection device 4. The battery system S is connected to a motor generator (MG) 6 via a power control unit (PCU) 5.

The secondary battery 1 supplies electric power to the MG 6 via the PCU 5. The secondary battery 1 has a plurality of battery cells. The plurality of battery cells are connected in series. Although the number of battery cells is four in FIG. 1, the number of battery cells is not limited to four. The number of battery cells may be four or more. Further, the plurality of battery cells may be connected in parallel.

Alternatively, the secondary battery 1 may have a plurality of battery stacks (not shown) each having a plurality of battery cells. In this case, the plurality of battery stacks may be connected in series or may be connected in parallel.

One end of each of the plurality of relays SMR-B and SMR-G is connected to each of both electrodes of the secondary battery 1. In the example of FIG. 1, one end of the relay SMR-B is connected to the positive electrode of the secondary battery 1. Further, one end of the relay SMR-G is connected to the negative electrode of the secondary battery 1. The relays SMR-B and SMR-G are switched on and off based on a control signal from the sticking detection device 4.

By turning off the relays SMR-B and SMR-G, the high-voltage side secondary battery 1 and the low-voltage side PCU 5 and MG 6 can be insulated. Further, by turning on the relays SMR-B and SMR-G, it is possible to connect the secondary battery on the high voltage side to the PCU5 and MG6 on the low voltage side.

The capacitor 2 is connected between the other ends of the relays SMR-B and SMR-G. The capacitor 2 is provided to smooth the voltage between the other ends of the relays SMR-B and SMR-G.

The insulation resistances 31 to 34 have resistance values of several MΩ, for example. The secondary battery 1 is electrically connected to the vehicle body (ground) through insulation resistors 31 to 34. One end of the insulation resistance 31 is connected to the positive electrode of the secondary battery 1, and the other end is connected to the ground. Moreover, one end of the insulation resistance 32 is connected to the negative electrode of the secondary battery 1, and the other end is connected to the ground.

One end of the insulation resistance 33 is connected to the positive electrode of the secondary battery 1 via the relay SMR-B, and the other end is grounded. Further, the insulation resistance 34 has one end connected to the negative electrode of the secondary battery 1 via the relay SMR-G and the other end grounded to the ground.

PCU 5 controls the output of electric power supplied from secondary battery 1 to MG 6. The PCU 5 also has a DCDC converter 51 and an inverter 52.

The DCDC converter 51 boosts the voltage of the secondary battery 1 smoothed by the capacitor 2. The DCDC converter 51 also has a discharge circuit (not shown) that discharges the capacitor 2. The discharge circuit (not shown) has, for example, a resistor and a switch, and turns on the switch to connect the capacitor 2 and the resistor to discharge the capacitor 2. The DCDC converter 51 discharges the capacitor 2 according to an instruction from a vehicle control device (not shown), for example, at a timing of turning off an ignition switch (not shown) of the vehicle. Inverter 52 converts the DC voltage boosted by DCDC converter 51 into an AC voltage and outputs it to MG6.

MG6 is driven based on the AC voltage output from inverter 52 to drive the vehicle. Further, MG 6 converts kinetic energy generated when the vehicle is braked into electric energy. MG6 outputs the converted electrical energy to secondary battery 1 via PCU5. As a result, the secondary battery 1 is charged.

The above-described relays SMR-B and SMR-G are mechanical relays that are switched on and off by moving a movable part, for example. There is a possibility that the relays SMR-B and SMR-G will be welded due to a large current flowing through the plurality of relays SMR-B and SMR-G, for example, and will remain stuck on without switching even if a control signal for switching off is input. There is.

The sticking detection device 4 determines whether sticking has occurred in the relays SMR-B and SMR-G, and detects the sticking state of each of the relays SMR-B and SMR-G when sticking has occurred. The sticking detection device 4 includes a pulse application unit 41, a voltage detection unit 42, and a control unit 43.

The pulse applying unit 41 is connected to the negative electrode of the secondary battery 1 via the coupling capacitor 40. One end of the coupling capacitor 40 is connected to the pulse applying unit 41 of the sticking detection device 4, and the other end is connected to the secondary battery 1. The coupling capacitor 40 electrically insulates the low voltage side sticking detection device 4 from the high voltage side secondary battery 1.

Further, the pulse applying unit 41 has a pulse generating circuit 411 and a resistor 412. The pulse generation circuit has one end installed at the ground and the other end connected to one end of the resistor 412. The other end of the resistor 412 is connected to the secondary battery 1 via the coupling capacitor 40.

The pulse generation circuit 411 generates a pulse signal. The generated pulse signal is applied to the secondary battery 1 via the resistor 412 and the coupling capacitor 40.

The voltage detection unit 42 is connected to the negative electrode of the secondary battery 1 via the coupling capacitor 40. The voltage detector 42 detects the voltage at one end (point A) of the coupling capacitor 40. The voltage detection unit 42 outputs the detected voltage to the control unit 43.

The control unit 43 is a microcomputer including a CPU (Central Processing Unit), a storage unit 435, and the like, and controls the entire sticking detection device 4. The control unit 43 is mounted in, for example, an ECU (Electric Control Unit). The control unit 43 includes a relay control unit 431, a sticking determination unit 432, and a sticking detection unit 434 as functions realized by software in a microcomputer.

The relay control unit 431 generates a control signal that switches ON/OFF of the relays SMR-B and SMR-G. The relay control unit 431 generates a control signal for turning on the relays SMR-B and SMR-G based on, for example, an instruction from the sticking determination unit 432 or the sticking detection unit 434. In addition, the relay control unit 431 outputs a control signal for turning on the relays SMR-B and SMR-G when supplying power from the secondary battery 1 to the MG6 or when supplying power from the MG6 to the secondary battery 1. To generate. In FIG. 1, the control lines from the relay control unit 431 to the relays SMR-B and SMR-G are omitted.

The sticking determination unit 432 determines whether at least one of the relays SMR-B and SMR-G is stuck. Specifically, the relay control unit 431 controls to turn off the relays SMR-B and SMR-G, and the pulse application unit 41 applies the pulse signal to the secondary battery 1. In this case, the sticking determination unit 432 acquires from the voltage detection unit 42 the voltage at the point A when the predetermined time T1 has elapsed from the rising of the pulse signal.

Here, when at least one of the relays SMR-B and SMR-G is fixed, as shown in FIG. 2, at the point A due to the influence of the stray capacitances SC1 and SC2 (see FIG. 1) generated in the battery system S. Compared with the case where the rising edge of the voltage to be detected is not fixed, the rising edge becomes much slower and the rising time becomes longer. Therefore, the voltage at the point A when the predetermined time T1 has elapsed from the rise of the pulse signal is lower when the relays SMR-B and SMR-G are fixed than when they are not fixed. Note that FIG. 2 is a graph showing the voltage at point A when a pulse signal is applied to the battery system S. The solid line in FIG. 2 shows the voltage when neither of the relays SMR-B and SMR-G is fixed. The two-dot chain line shows the voltage when the relays SMR-B and SMR-G are fixed.

The sticking determination unit 432 determines whether the relays SMR-B and SMR-G are stuck by comparing the acquired voltage at the point A with the threshold voltage Th1 (see FIG. 2).

Hereinafter, the reason why the voltage waveform at the point A becomes dull when the relays SMR-B and SMR-G are fixed will be described with reference to FIGS. 3A and 3B. FIG. 3A is a diagram showing an equivalent circuit when the relays SMR-B and SMR-G are fixed. FIG. 3B is a diagram showing an equivalent circuit when the relays SMR-B and SMR-G are not fixed. The resistance value R1 in FIGS. 3A and 3B indicates the combined resistance value of the insulation resistors 31 and 32, and the resistance value R2 indicates the combined resistance value of the insulation resistors 33 and 34.

As shown in FIG. 3A, the other end of the pulse circuit 411 and the other ends of the insulating resistors 31 to 34 are connected via the ground. Therefore, in the battery system S, a closed circuit including the pulse circuit 411, the resistor 412, the point A, and the coupling capacitor 40 is formed. Further, as shown in FIG. 1, a stray capacitance SC1 is generated between the insulation resistance 32 and the ground. A stray capacitance SC2 is generated between the insulation resistance 34 and the ground.

As shown in FIG. 3A, when the relays SMR-B and SMR-G are fixed, the relays SMR-B and SMR-G are turned on even if the control signal of the relay control unit 431 is input. There is. Therefore, in the closed circuit including the pulse generation circuit 411 and the point A, the coupling capacitor 40, the parallel circuit F1 of the combined resistance of the insulation resistances 31 and 32 and the stray capacitance SC1, and the combined resistance of the insulation resistances 33 and 34 are included. And a parallel circuit F2 of the stray capacitance SC2. Due to the influence of the coupling capacitor 40 and the two stray capacitances SC1 and SC2, the voltage waveform at the point A becomes significantly dull, and the rise time of the voltage detected by the voltage detection unit 42 becomes long.

On the other hand, when the relays SMR-B and SMR-G are not fixed, the relays SMR-B and SMR-G are turned off according to the control signal of the relay control unit 431, as shown in FIG. 3B. Accordingly, the closed circuit including the pulse generation circuit 411 and the point A does not include the parallel circuit F2 of the combined resistance of the insulation resistors 33 and 34 and the stray capacitance SC2, but includes the coupling capacitor 40 parallel circuit F1. .. Therefore, the voltage waveform at the point A is affected by the coupling capacitor 40 and the stray capacitance SC1, but is not affected by the stray capacitance SC2. Therefore, the voltage waveform at the point A is not as blunt as when the relays SMR-B and SMR-G are fixed, and the rise time of the voltage detected by the voltage detection unit 42 is short.

The sticking determination unit 432 determines whether or not the relays SMR-B and SMR-G are stuck based on the rising time of the voltage waveform at the point A. Specifically, in the sticking determination unit 432, a point A after a predetermined time T1 has elapsed since the pulse application unit 41 applied the pulse signal and the relay control unit 431 controlled to turn off the relays SMR-B and SMR-G. When the voltage of 1 is smaller than the threshold voltage Th1, it is determined that the relays SMR-B and SMR-G are fixed. When the sticking determination unit 432 determines that the relays SMR-B and SMR-G are fixed, it notifies the sticking detection unit 434 to that effect.

In this way, the sticking determination unit 42 determines whether or not the relays SMR-B and SMR-G are stuck based on the rising time of the voltage waveform detected by the voltage detection unit 42, thereby improving the sticking determination accuracy. You can

Further, the pulse applying unit 41 and the voltage detecting unit 42 also operate as a circuit for detecting a leakage of the secondary battery 1, for example. In this way, by sharing the circuit for performing the sticking determination and the circuit for performing the leakage detection, it is possible to accurately determine the sticking while suppressing an increase in the circuit scale.

When determining the presence or absence of sticking, the relay control unit 431 generates a control signal to turn off both the relays SMR-B and SMR-G at the same time. In this way, even if the relays SMR-B and SMR-G are not controlled individually but are controlled simultaneously, it is possible to accurately detect whether or not the relays SMR-B and SMR-G are fixed.

Although FIG. 3A illustrates a case where both the relays SMR-B and SMR-G are fixed, the same is true when either one of the relays SMR-B and SMR-G is fixed. That is, even if either one of the relays SMR-B and SMR-G is fixed, the closed circuit including the pulse generation circuit 411 includes the stray capacitance SC2, and the voltage waveform at the point A is greatly blunted. Therefore, also in this case, as in the case where both the relays SMR-B and SMR-G are stuck, the sticking determination unit 432 can determine whether there is sticking.

Returning to FIG. When the sticking determination unit 432 detects the sticking, the sticking detection unit 434 identifies the sticking point of each of the relays SMR-B and SMR-G. That is, the sticking detection unit 434 controls the relays SMR-B and SMR-G to be turned off, and the relays SMR-B and SMR-G according to the voltage fluctuation of the insulation resistance R32 due to the discharge of the capacitor 2. The stuck state of each is detected.

As described above, the DCDC converter 51 discharges the capacitor 2 at the timing of turning off the ignition switch of the vehicle, for example. Therefore, the sticking detection device 4 detects the sticking of the relays SMR-B and SMR-G in synchronization with the timing of turning off the ignition switch of the vehicle. As a result, the sticking detection device 4 can detect the sticking of the relays SMR-B and SMR-G at least once while the vehicle is traveling, without controlling the discharge of the capacitor 2.

Specifically, the sticking detection unit 434 first controls the relays SMR-B and SMR-G to be turned off via the relay control unit 431. Next, the sticking detection unit 434 acquires the voltage at the point A from the voltage detection unit 42. After the capacitor 2 is discharged, the sticking detection unit 434 acquires the voltage at the point A from the voltage detection unit 42 again.

The sticking detection unit 434 detects the sticking state of each of the relays SMR-B and SMR-G according to the fluctuation of the voltage at the point A acquired twice. When the voltage at the point A after discharging the capacitor 2 is higher than that before discharging, the sticking detection unit 434 detects that the relay SMR-G is stuck and the relay SMR-B is not stuck. .. When the voltage at the point A after discharging is lower than that before discharging, the sticking detecting unit 434 detects that the relay SMR-B is stuck and the relay SMR-G is not stuck. When the voltage at the point A after the discharge has not substantially changed from before the discharge, that is, when the difference between the voltages at the point A before and after the discharge is within a predetermined voltage range, the sticking detection unit 434 determines that the relays SMR-B, SMR. -Detects that both G are fixed.

Hereinafter, the relationship between the fixation of the relays SMR-B and SMR-G and the voltage fluctuation at the point A will be described with reference to FIGS. 4A to 7. In order to simplify the description, the resistance values R of the insulation resistances 31 to 34 are assumed to be the same.

First, the case where the relay SMR-G is fixed will be described with reference to FIGS. 4A and 4B.

FIG. 4A is a diagram showing an equivalent circuit of the battery system S before the discharge of the capacitor 2 when the relay SMR-G is fixed. Further, FIG. 4B is a diagram showing an equivalent circuit of the battery system S after the capacitor 2 is discharged when the relay SMR-G is fixed.

In FIG. 4A and FIG. 4B, illustration of components unnecessary for description is omitted. Further, the pulse generation circuit 411 and the resistor 422 have a smaller impedance than the insulation resistors 31 to 34, and have a small influence on the equivalent circuit. Therefore, in order to simplify the description, FIGS. 4A and 4B show an equivalent circuit in which the pulse generation circuit 411 and the resistor 422 are not considered. Similarly, FIGS. 6A to 7 described later also show an equivalent circuit in which unnecessary components, the pulse generation circuit 411, and the resistor 422 are omitted.

The capacitor 2 is charged to the same voltage V as the secondary battery 1 while the relays SMR-B and SMR-G are on.

As shown in FIG. 4A, it is assumed that the relay control unit 431 controls the relays SMR-B and SMR-G to be turned off when the relay SMR-G is fixed. In this case, one ends of the insulation resistors 31 and 33 are open, but one ends of the insulation resistors 32 and 34 are connected to each other. Therefore, the voltage V0 across the insulation resistance 32 connected to the negative electrode of the secondary battery 1, that is, the voltage V0 across BC is a value obtained by dividing the voltage V of the capacitor 2 by the insulation resistances 33 and 34. Here, since the insulation resistors 33 and 34 have the same resistance value R, the voltage V0 between BC is about one half of the voltage V of the capacitor 2.

Further, since the points B and A are connected via the ground, the voltage between BA becomes the same voltage V0 as between BC.

Next, a case where the capacitor 2 is discharged will be described with reference to FIG. 4B. For example, when all the charges of the capacitor 2 are discharged and the voltage becomes 0 V, the capacitor 2 seems to be short-circuited, and one ends of the insulating resistors 33 and 34 are connected to each other. In this case, the insulation resistances 32 to 34 are connected in parallel, and the combined resistance value of the insulation resistances 32 to 34 is about one third of each resistance value R of the insulation resistances 32 to 34. That is, the combined resistance value R0 between BC becomes smaller than the resistance value R of the insulation resistance 31.

The voltage V1 across the insulation resistance 32 is a value obtained by dividing the voltage V of the secondary battery 1 by the insulation resistance 31 and the combined resistance of the insulation resistances 32 to 34. Therefore, the voltage V1 across the insulation resistance 32, that is, the voltage V1 between BC is smaller than half the voltage V of the secondary battery 1 and smaller than the voltage V0 between BC before discharging.

Further, since the point B and the point A are connected via the ground, the voltage between BA becomes the same voltage V1 as between BC and becomes smaller than the voltage V0 between BC before discharge.

When the voltage changes, the coupling capacitor 40 tries to send a current to the changed side. Therefore, when the voltage between BC drops before and after the capacitor 2 is discharged, the current I1 flows from the voltage detection unit 42 to the point B. As a result, as indicated by the alternate long and short dash line in FIG. 5, the voltage at point A detected by the voltage detection unit 42 increases based on the low-potential-side reference potential. Note that FIG. 5 is a graph showing the voltage fluctuation at the point A detected by the voltage detection unit 42.

The sticking detection unit 434 detects that the voltage at the point A detected by the voltage detection unit 42 has risen, so that the voltage of the insulation resistance 32 connected to the negative electrode of the secondary battery 1 has dropped from the voltage V0 to the voltage V1. To detect. In this case, the sticking detection unit 434 detects the sticking of the relay SMR-G.

In this way, the sticking detection unit 434 can detect the sticking of the relay SMR-G by detecting the voltage drop of the insulation resistance 32, and can specify the sticking point.

Next, a case where the relay SMR-B is fixed will be described with reference to FIGS. 6A and 6B.

FIG. 6A is a diagram showing an equivalent circuit of the battery system S before discharging the capacitor 2 when the relay SMR-B is fixed. Further, FIG. 6B is a diagram showing an equivalent circuit of the battery system S after the capacitor 2 is discharged when the relay SMR-B is fixed.

The capacitor 2 is charged to the same voltage V as the secondary battery 1 while the relays SMR-B and SMR-G are on.

As shown in FIG. 6A, it is assumed that when relay SMR-B is fixed, relay control unit 431 controls relays SMR-B and SMR-G to turn off. In this case, one end of the insulation resistors 32 and 34 is open, but one end of the insulation resistors 31 and 33 is connected to each other.

Therefore, the voltage V0 across the insulation resistance 32 connected to the negative electrode of the secondary battery 1, that is, the voltage V0 across BC is a value obtained by dividing the voltage V of the secondary battery 1 by the insulation resistances 31 and 32. Here, since the resistance values R of the insulation resistors 31 and 32 are equal values, the voltage V0 between BC is about one half of the voltage V of the secondary battery 1.

Further, since the points B and A are connected via the ground, the voltage between BA becomes the same voltage V0 as between BC.

Next, a case where the capacitor 2 is discharged will be described with reference to FIG. 6B. For example, when all the charges of the capacitor 2 are discharged and the voltage becomes 0 V, the capacitor 2 seems to be short-circuited, and one ends of the insulating resistors 33 and 34 are connected to each other. In this case, the insulation resistances 31, 33, 34 are connected in parallel, and the combined resistance value of the insulation resistances 31, 33, 34 is about one third of the resistance value R of each of the insulation resistances 31, 33, 34. Becomes That is, the combined resistance value R0 between CDs becomes smaller than the resistance value R of the insulation resistance 32.

The voltage V2 across the insulation resistance 32 is a value obtained by dividing the voltage V of the secondary battery 1 by the insulation resistance 32 and the combined resistance of the insulation resistances 31, 33, and 34. Therefore, the voltage V2 across the insulation resistance 32, that is, the voltage V2 between BC is larger than half the voltage V of the secondary battery 1 and is larger than the voltage V0 between BC before discharging.

Further, since the point B and the point A are connected via the ground, the voltage between BA becomes the same voltage V2 as between BC and becomes larger than the voltage V0 between BC before discharge.

When the voltage V0 between BC changes to the voltage V2 before and after the discharge of the capacitor 2, the coupling capacitor 40 tries to pass the changed current, and the current I2 flows from the point B to the voltage detection unit 42. As a result, the voltage at the point A detected by the voltage detection unit 42 decreases, as indicated by the chain double-dashed line in FIG.

The sticking detection unit 434 detects that the voltage of the insulation resistance 32 has risen from the voltage V0 to V2 by detecting the voltage drop at the point A detected by the voltage detection unit 42. In this case, the sticking detection unit 434 detects the sticking of the relay SMR-B.

In this way, the sticking detection unit 434 can detect the sticking of the relay SMR-B by detecting the voltage increase of the insulation resistance 32, and can specify the sticking point.

Next, a case where both the relays SMR-B and SMR-G are fixed will be described with reference to FIG. FIG. 7 is a diagram showing an equivalent circuit of the battery system S when both the relays SMR-B and SMR-G are fixed.

The capacitor 2 is charged to the same voltage V as the secondary battery 1 while the relays SMR-B and SMR-G are on.

As shown in FIG. 7, it is assumed that the relay control unit 431 controls the relays SMR-B and SMR-G to be turned off when both the relays SMR-B and SMR-G are fixed. In this case, the relays SMR-B and SMR-G remain on. Therefore, one ends of the insulation resistors 31 and 33 are connected to each other, and one ends of the insulation resistors 32 and 34 are connected to each other.

In this case, even if the capacitor 2 is discharged, the capacitor 2 will be charged by the secondary battery 1. Therefore, the capacitor 2 is not discharged, and the voltage of the capacitor 2 remains equal to the voltage V of the secondary battery 1.

Therefore, the voltage V0 of the insulation resistance 32 connected to the negative electrode of the secondary battery 1, that is, the voltage V0 between BC does not change and has a substantially constant value. Therefore, the voltage between BA does not change and becomes almost the voltage V0. As a result, as shown by the solid line in FIG. 5, the voltage at the point A detected by the voltage detection unit 42 does not fluctuate and becomes substantially constant.

The sticking detection unit 434 detects that the voltage of the insulation resistance 32 is substantially constant by detecting that the voltage at the point A detected by the voltage detection unit 42 is substantially constant. In this case, the sticking detection unit 434 detects the sticking of both the relays SMR-B and SMR-G.

In this way, the sticking detection unit 434 can detect the sticking of both the relays SMR-B and SMR-G by detecting that the voltage of the insulation resistance 32 is substantially constant, and specify the sticking point. You can

As described above, the sticking detection unit 434 detects the voltage fluctuation of the insulation resistance 32 due to the discharge of the capacitor 2 based on the detection result of the voltage detection unit 42, whereby the sticking point can be specified and the relays SMR-B and SMR can be specified. It is possible to detect the adhered state of −G.

Further, by discharging the capacitor 2 by the DCDC converter 51, the sticking detection unit 434 can detect the stuck state of the relays SMR-B and SMR-G without adding a new circuit. Therefore, an increase in circuit scale can be suppressed.

Here, according to the difference between the voltage at the point A when the voltage of the capacitor 2 is substantially equal to the voltage V of the secondary battery 1 and the voltage at the point A when the voltage of the capacitor 2 is approximately 0V, The case where the sticking detection unit 434 detects the stuck state of the relays SMR-B and SMR-G has been described, but the present invention is not limited to this. The fixed state of the relays SMR-B and SMR-G may be detected based on the voltage change at the point A when the voltage of the capacitor 2 changes due to the discharge of the capacitor 2. Therefore, for example, the voltage of the capacitor 2 before discharging may not necessarily be charged so as to be equal to the voltage V of the secondary battery 1. Further, the voltage at the point A may be detected before the voltage of the capacitor 2 becomes almost 0V.

The storage unit 435 illustrated in FIG. 1 stores information necessary for processing performed by each unit of the control unit 43, such as a threshold Th1 used when the sticking determination unit 432 makes a sticking determination. The storage unit 435 also stores necessary information performed by each unit of the control unit 43. The storage unit 435 is, for example, a RAM (Random Access Memory), a semiconductor memory element such as a flash memory, or a storage device such as a hard disk or an optical disk.

Next, the abnormality detection process performed by the sticking detection device 4 will be described with reference to FIGS. 8 to 10. The sticking detection device 4 detects sticking of the relays SMR-B and SMR-G as an abnormality in the abnormality detection processing. FIG. 8 is a flowchart showing the abnormality detection processing according to this embodiment. It is assumed that the sticking detection device 4 executes the abnormality detection process shown in FIG. 8 at least once while the vehicle is traveling, for example, when the ignition switch of the vehicle is turned off.

First, the sticking detection device 4 executes a sticking determination process (step S101). The sticking determination process will be described later with reference to FIG. The sticking detection device 4 determines whether or not it is determined that there is sticking in the sticking determination processing (step S102).

If it is not determined that there is sticking (step S102; No), the process ends. When it is determined that there is sticking (step S102; Yes), the sticking detection device 4 executes sticking determination processing to identify the sticking point (step S103). The sticking determination process will be described later with reference to FIG.

FIG. 9 is a flowchart showing the sticking determination processing according to this embodiment. The sticking detection device 4 applies a pulse signal to the negative electrode of the secondary battery 1 via the coupling capacitor 40 (step S201). Next, the sticking detection device 4 controls to turn off the relays SMR-B and SMR-G (step S202). If another control device turns off the relays SMR-B and SMR-G when the ignition switch of the vehicle is turned off, step S202 may be omitted. In this case, the process of FIG. 8 may be started when the information that the relays SMR-B and SMR-G are turned off is obtained from the other control device by communication.

The sticking detection device 4 detects the voltage at the point A after the predetermined period T1 from the rise of the pulse signal (step S203). The sticking detection device 4 compares the detected voltage with the threshold Th1 (step S204).

When the detected voltage is equal to or higher than the threshold Th1 (step S204; No), the sticking detection device 4 determines that there is no sticking (step S205), and ends the process. On the other hand, when the detected voltage is smaller than the threshold Th (step S204; Yes), the sticking detection device 4 determines that there is sticking (step S206), and ends the process.

FIG. 10 is a flowchart showing the sticking detection processing according to this embodiment. As shown in FIG. 10, the sticking detection device 4 controls the relays SMR-B and SMR-G to be turned on and charges the capacitor 2 (step S301). Next, the sticking detection device 4 controls the relays SMR-B and SMR-G to be off (step S302), and detects the voltage at the point A (step S303).

When the capacitor 2 is discharged, that is, when a predetermined time that is required for discharging has elapsed (step S304), the sticking detection device 4 detects the voltage at the point A (step S305). The sticking detection device 4 detects the stuck state of the relays SMR-B and SMR-G based on the difference between the voltage detected in step S303 and the voltage detected in step S305 (step S306).

If the capacitor 2 has already been charged to the predetermined voltage, step S301 may be omitted.

As described above, according to the sticking detection device 4 according to the present embodiment, the relay SMR-B, by detecting the voltage fluctuation of the insulation resistance 32 connected to the negative electrode of the secondary battery 1 due to the discharge of the capacitor 2. The stuck state of SMR-G can be detected.

(Modification)
Next, a modified example of the battery system S according to the present embodiment will be described with reference to FIGS. 11 and 12. FIG. 11 is a diagram showing the configuration of the battery system S2 according to this modification. The battery system S2 shown in FIG. 11 is the same as the battery system S shown in FIG. 1 except that the control unit 43B includes a sticking determination unit 432B, an electric leakage detection unit 436, and a frequency control unit 437. The same components as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted.

The frequency control unit 437 of the control unit 43B controls the frequency of the pulse signal generated by the pulse generation circuit 411. The frequency control unit 437 applies to the secondary battery 1 a higher frequency than the frequency when the leakage detection unit 436 detects the leakage of the secondary battery 1 when detecting the fixation of the relays SMR-B and SMR-G. The pulse applying unit 41 is controlled so that The frequency control unit 437 controls the pulse generation circuit 411 so as to generate a pulse signal of several Hz when detecting a leak and a pulse signal of several hundred Hz when detecting sticking.

The leakage detection unit 436 detects leakage of the secondary battery 1 caused by a decrease in the resistance value R of the insulation resistances 31 to 34. The leakage detection unit 436 detects the leakage of the secondary battery 1 according to the peak value of the voltage at the point A detected by the voltage detection unit 42 when the pulse application unit 41 applies the pulse signal to the secondary battery 1. .. It should be noted that the electric leakage detection is periodically performed at a predetermined cycle while the ignition switch is on.

The sticking determination unit 432B determines whether or not the relays SMR-B and SMR-G are fixed according to the voltage at the point A when the pulse application unit 41 applies a pulse signal of, for example, several hundred Hz.

Here, the voltage at point A when a high-frequency pulse signal is applied will be described with reference to FIG. FIG. 12 is a graph showing the voltage at point A when a high frequency pulse signal is applied to the battery system S2. The solid line in FIG. 12 is a graph showing the voltage waveform at point A when sticking has not occurred, and the two-dot chain line is a graph showing the voltage waveform at point A when sticking has occurred.

As described above, when sticking occurs, the voltage waveform at the point A when the pulse signal is applied to the secondary battery becomes dull due to the influence of the stray capacitance SC2 generated in the battery system S2. As shown in FIG. 12, when the frequency of the pulse signal is high, the voltage waveform at the point A becomes dull due to the influence of the stray capacitance SC2, the peak value does not rise, and the peak value of the voltage at the point A decreases.

Therefore, the sticking determination unit 432B according to the present modification determines that sticking has occurred in the relays SMR-B and SMR-G when the voltage at the point A is smaller than the predetermined threshold Th2 (see FIG. 12). ..

As described above, the battery system S2 according to the present modification compares the voltage at the point A when a pulse signal having a high frequency is applied with the predetermined threshold Th2, and thus does not wait for the voltage at the point A to rise. Since it becomes possible to determine the presence or absence of sticking, the determination time can be shortened.

In addition, in the above-described embodiment and modified example, the case where the relays SMR-B and SMR-G are fixed to be on by welding is described, but the present invention is not limited to this. For example, it is possible that the relays SMR-B and SMR-G are in an uncontrollable state and cannot be switched from on to off due to disconnection of a control line that controls the relays SMR-B and SMR-G. As described above, even when the relays SMR-B and SMR-G are stuck due to the abnormality on the control side, the sticking detection device 4 can detect the sticking.

The relays SMR-B and SMR-G are not limited to mechanical relays. For example, a semiconductor relay or the like may be used. In this case, the sticking detection device 4 detects a short circuit abnormality of the relay as sticking. Thus, even if various switches are applied as the relays SMR-B and SMR-G, the sticking detection device 4 must detect the sticking in which the relays SMR-B and SMR-G are not switched off. You can

Further, in the above-described embodiment and modification, the pulse applying unit 41 and the voltage detecting unit 42 are connected to the negative electrode of the secondary battery 1, but the present invention is not limited to this. The pulse applying unit 41 and the voltage detecting unit 42 may be connected to the positive electrode of the secondary battery. In this case, the sticking detection device 4 detects the stuck state of the relays SMR-B and SMR-G according to the change in the voltage of the insulation resistance 31 connected to the positive electrode of the secondary battery 1.

Further, in the above-described embodiment and modification, it is assumed that the DCDC converter 51 discharges the capacitor 2, but the present invention is not limited to this. Good.

Further, in the above-described embodiment and modification, the sticking detection device 4 detects the sticking according to the timing at which the capacitor 2 is discharged, such as the timing at which the ignition switch is turned off. However, the present invention is not limited to this. For example, the sticking detection device 4 may include a control unit that controls the discharge of the capacitor 2, and the sticking detection device 4 may discharge the capacitor 2 according to the timing at which the sticking detection device 4 detects the sticking. In this way, the sticking detection device 4 controls the discharge of the capacitor 2 so that the sticking can be detected at an arbitrary timing.

Further, in the above-described embodiment and modification, the sticking determination units 432, 432B determine the sticking of the relays SMR-B, SMR-G, and then the sticking detection unit 434 sets the sticking points of the relays SMR-B, SMR-G. Although the case of specifying is described, the present invention is not limited to this. For example, the sticking determination units 432 and 432B may be omitted, and the sticking detection unit 434 may specify the sticking points of the relays SMR-B and SMR-G.

The sticking detection device 4 according to the above-described embodiment and modification includes the voltage detection unit 42 and the sticking detection unit 434. The voltage detection unit 42 is connected to one pole of the secondary battery 1 via the coupling capacitor 40 and detects a change in the voltage of the insulation resistance 32 provided between one pole of the secondary battery 2 and the ground. To do. The sticking detection unit 434 controls the plurality of relays SMR-B and SMR-G in a state where the plurality of relays SMR-B and SMR-G, one ends of which are respectively connected to both electrodes of the secondary battery 1, are controlled to be off. The fixed states of the plurality of relays SMR-B and SMR-G are respectively detected according to the fluctuation of the voltage detected by the voltage detection unit 42 due to the discharge of the capacitor 2 connected between the other ends.

As a result, the sticking detection device 4 detects the stuck states of the relays SMR-B and SMR-G, respectively, according to the voltage fluctuation of the insulation resistance 32 connected to the negative electrode of the secondary battery 1 due to the discharge of the capacitor 2. You can

In the sticking detection unit 434 of the sticking detection device 4 according to the above-described embodiment and modification, the voltage V1 of the insulation resistance 32 after discharging the capacitor 2 is higher than the voltage V0 before discharging, based on the detection result of the voltage detecting unit 42. When (V2>V0), the sticking of the relay SMR-RB connected to the other pole of the secondary battery 1 is detected.

Accordingly, the sticking detection unit 434 of the sticking detection device 4 can detect the sticking of the relay SMR-B by detecting the voltage increase of the insulation resistance 32, and can specify the sticking point.

In the sticking detection unit 434 of the sticking detection device 4 according to the above-described embodiment and modification, the voltage V1 of the insulation resistance 32 after discharging the capacitor 2 is lower than the voltage V0 before discharging, based on the detection result of the voltage detecting unit 42. When (V1<V0), the fixation of the relay SMR-RG connected to one pole of the secondary battery 1 is detected.

Accordingly, the sticking detection unit 434 of the sticking detection device 4 can detect the sticking of the relay SMR-G by detecting the voltage drop of the insulation resistance 32, and can specify the sticking point.

When the sticking detection unit 434 of the sticking detection device 4 according to the above-described embodiment and the modification is based on the detection result of the voltage detection unit 42, the difference in voltage of the insulation resistance 32 before and after discharging the capacitor 2 is within a predetermined range. First, the sticking of the plurality of relays SMR-B and SMR-G connected to each of both poles of the secondary battery 2 is detected.

Accordingly, the sticking detection unit 434 of the sticking detection device 4 can detect the sticking of both the relays SMR-B and SMR-G by detecting that the voltage of the insulation resistance 32 is substantially constant, and the sticking point Can be specified.

The sticking detection device 4 according to the above-described embodiment further includes a pulse application unit 41 and a sticking determination unit 432. The pulse applying unit 41 applies a pulse signal to the secondary battery 1 via the coupling capacitor 40. The sticking determination unit 432 determines whether or not at least one of the plurality of relays SMR-B and SMR-G is stuck based on the voltage detected by the voltage detection unit 42 after a lapse of a predetermined time T1 from the rise of the pulse signal. ..

Accordingly, the sticking detection device 4 can determine whether the relays SMR-B and SMR-G are stuck based on the rise time of the voltage waveform detected by the voltage detection unit 42, and the relay SMR-B and SMR-B can be accurately determined. It is possible to determine whether or not the SMR-G is fixed.

The sticking detection device 4 according to the modified example described above further includes a pulse applying unit 41 and a sticking determination unit 432B. The pulse applying unit 41 applies a pulse signal having a higher frequency than the pulse signal applied when detecting the leakage of the secondary battery 1 to the secondary battery 1 via the coupling capacitor 40. The sticking determination unit 432B determines whether or not at least one of the plurality of relays SMR-B and SMR-G is fixed, based on the voltage detected by the voltage detection unit 42 when the pulse application unit 41 applies the pulse signal. ..

As a result, the sticking detection device 4 can shorten the sticking determination time as compared with the case where the rise time of the voltage waveform detected by the voltage detection unit 42 is detected.

Further effects and modifications can be easily derived by those skilled in the art. As such, the broader aspects of the present invention are not limited to the specific details and representative embodiments shown and described above. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept defined by the appended claims and their equivalents.

1 Secondary Battery 2 Capacitors 31-34 Insulation Resistance 4 Sticking Detection Device 41 Pulse Applying Section 42 Voltage Detection Section 43 Control Section 432 Sticking Determining Section 434 Sticking Detection Section SMR-B, SMR-G Relay

Claims (7)

A voltage detection unit that is connected to one pole of a secondary battery via a coupling capacitor and that detects a variation in voltage of an insulation resistance provided between the one pole of the secondary battery and the ground,
Detected by the voltage detection unit by discharging a capacitor connected between the other ends of the plurality of relays in a state where a plurality of relays, one end of which is connected to each of the two poles of the secondary battery, are controlled to be off. A sticking detection unit that detects a stuck state of each of the plurality of relays according to a change in voltage,
A sticking detection device comprising: The sticking detection unit,
Based on the detection result of the voltage detection unit, when the voltage of the insulation resistance after discharging the capacitor is higher than the voltage before discharging, the fixation of the relay connected to the other pole of the secondary battery It detects, The sticking detection apparatus of Claim 1 characterized by the above-mentioned. The sticking detection unit,
Based on the detection result of the voltage detection unit, if the voltage of the insulation resistance after discharging the capacitor is lower than the voltage before discharging, fixation of the relay connected to the one pole of the secondary battery The sticking detection device according to claim 1 or 2, wherein The sticking detection unit,
Based on the detection result of the voltage detection unit, when the difference in the voltage of the insulation resistance before and after the discharge of the capacitor is within a predetermined range, the plurality of relays connected to each of the both electrodes of the secondary battery The sticking detection device according to claim 1, 2 or 3, wherein the sticking is detected. A pulse applying unit for applying a pulse signal to the secondary battery via the coupling capacitor,
Based on the voltage detected by the voltage detection unit after a lapse of a predetermined time from the rise of the pulse signal, a sticking determination unit that determines whether at least one of the plurality of relays is fixed,
The sticking detection device according to any one of claims 1 to 4, further comprising: A pulse signal having a higher frequency than the pulse signal applied when detecting the leakage of the secondary battery, a pulse applying unit for applying the secondary battery through the coupling capacitor,
Based on the voltage detected by the voltage detection unit at the time of applying the pulse signal by the pulse applying unit, a fixation determination unit that determines whether at least one of the plurality of relays is fixed,
The sticking detection device according to any one of claims 1 to 4, further comprising: A secondary battery,
A plurality of relays, one end of which is connected to each of both electrodes of the secondary battery,
A capacitor connected between the other ends of the plurality of relays;
An insulation resistance provided between one pole of the secondary battery and the ground,
A voltage detection unit that is connected to the one pole of the secondary battery via a coupling capacitor, and detects a variation in the voltage of the insulation resistance,
In a state where the plurality of relays are controlled to be off, a sticking detection unit that detects a stuck state of each of the plurality of relays according to a change in voltage detected by the voltage detection unit due to discharge of the capacitor,
A battery system comprising:

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