JP2008189010A - Power source apparatus for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect an inner resistance value of a traveling battery regardless of a traveling condition of a vehicle without uselessly discharging a battery, and accurately detect an inner resistance value of a traveling battery utilizing a precharge of a capacitor without a dedicated discharging resistance or switch. <P>SOLUTION: This power source apparatus for a vehicle comprises a chargeable traveling battery 1, a contactor 2 connecting the traveling battery 1 to a load 10, a precharge circuit 3 paralelly connected to the contactor 2 and precharging a capacitor 13, and a control circuit 4 controlling the precharge circuit 3 and the contactor 2. The precharge circuit 3 comprises a precharge resistance 6 limiting a precharge current, and a precharge switch 7. The control circuit 4 is equipped with a detection circuit 8 inside for switching the precharge switch 7 on, flowing a charging current of the capacitor 13 to the precharge resistance 6 and detecting an inner resistance value (R) of the traveling battery 1. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power supply device for a vehicle including a control circuit that detects an internal resistance value of a traveling battery.

  The internal resistance value of the battery is one of important parameters indicating the state of the battery. Since the internal resistance value increases as the battery deteriorates, the degree of deterioration of the battery can be determined by detecting the internal resistance value. Further, when calculating the remaining capacity by integrating the charging / discharging currents of the battery, the remaining capacity can be calculated more accurately by detecting the power consumed by the internal resistance value. In particular, since a power supply device for a vehicle is required to extend the life of a battery, it is important to accurately detect the degree of deterioration of the battery. This is because it is possible to charge and discharge the battery in an optimal state while controlling the output of the battery according to the degree of deterioration of the battery and extending the life of the battery. In order to realize these things, a power supply device for a vehicle that detects an internal resistance value of a battery has been developed. (See Patent Document 1)

  Patent document 1 describes the apparatus which detects the internal resistance value of the battery during driving | running | working of a vehicle. This device calculates the internal resistance value Rc during charging from the slope of the voltage-current approximate line during charging. Further, the internal resistance value Rcd at the time of charging / discharging is calculated from the slope of the voltage-current approximate straight line at the time of charging / discharging. The internal resistance value of the battery is detected from the detected internal resistance value during charging and the internal resistance value during charging and discharging.

Further, Patent Document 2 measures the battery voltages Vd and Vc and the currents Id and Ic at the time when it is estimated that the SOC of the battery at the time of discharging and charging of the hybrid vehicle battery is substantially the same. The internal resistance value is detected based on the measured values of the voltages Vd and Vc and the currents Id and Ic during charging.
JP 2006-126172 A JP 2000-21455 A

  The power supply device for a vehicle described in Patent Documents 1 and 2 detects the internal resistance value by detecting the voltage and current of the battery when the battery is charged or discharged. In this device, the battery is charged, and the internal resistance value is detected by charging and detecting the voltage and current. Therefore, the timing for detecting the internal resistance value is specified as a state where the battery is charged and discharged. In addition, the device that detects the internal resistance value in a state where the battery is charged / discharged is such that the power for discharging the battery is specified by the magnitude of the load, and the state for charging the battery is specified by the running state of the vehicle, etc. However, it is not necessarily a preferable current for detecting the internal resistance value. This is because the current of the battery is specified by other factors such as the running state of the vehicle and is not necessarily a preferable current for detecting the internal resistance value. For this reason, since the internal resistance value is detected by detecting the voltage and current of the battery in a plurality of states with different currents, there is a drawback that it takes time to detect the internal resistance value. This drawback can be eliminated by connecting a discharge resistor for detecting the internal resistance value in series with the battery, and discharging the battery to detect the voltage. However, according to this structure, it is necessary to discharge the battery wastefully in order to detect the internal resistance value of the battery. Further, it is necessary to provide a dedicated discharge resistor for detecting the internal resistance value, and further to provide a switch for connecting the discharge resistor to the battery. Furthermore, in order to accurately detect the internal resistance value of a small battery, it is necessary to reduce the resistance value of the discharge resistance. A discharge resistor having a small resistance value increases the power consumption of the battery. This is because the power consumption of the discharge resistor is inversely proportional to the resistance value and proportional to the square of the battery voltage. For this reason, the electric power which a battery consumes wastefully in order to detect an internal resistance value becomes large. Further, it is necessary to use a discharge resistor having a large wattage, which increases the component cost. Furthermore, a space for providing a large discharge resistance is also required.

  The present invention has been developed for the purpose of solving such drawbacks. An important object of the present invention is to detect the internal resistance value of the traveling battery without wastefully discharging the battery, regardless of the traveling state of the vehicle, and further to use a precharge resistor for precharging the load capacitor. Therefore, a dedicated discharge resistor is provided to detect the internal resistance value, and a dedicated switch for connecting this discharge resistor to the battery is not required. An object of the present invention is to provide a power supply device for a vehicle that can accurately detect the internal resistance value of a battery for traveling by using charge.

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 includes a battery 1 for traveling that can be charged, a contactor 2 that connects the traveling battery 1 to a load 10, and a signal that is connected in parallel to the contactor 2 and that is input from an ignition switch 14 of the vehicle. The precharge circuit 3 for precharging the capacitor 13 of the load 10 and the control circuit 4 for controlling the precharge circuit 3 and the contactor 2 are provided. The precharge circuit 3 includes a precharge resistor 6 that limits a precharge current for charging the capacitor 13 and a precharge switch 7 connected in series to the precharge resistor 6. Further, in the vehicle power supply device, the control circuit 4 switches on the precharge switch 7 and causes the charging current of the capacitor 13 to flow through the precharge resistor 6 to detect the internal resistance value (R) of the traveling battery 1. A detection circuit 8 is incorporated.

According to a second aspect of the present invention, in addition to the configuration of the first aspect, the detection circuit 8 includes the open-circuit voltage (Vocv) of the traveling battery 1 when the precharge switch 7 is turned off, and the precharge. When the switch 7 is on, the load voltage (Vccv) of the battery 1 for traveling and the current (I) of the precharge resistor 6 are detected, and the traveling voltage is detected from the open voltage (Vocv), load voltage (Vccv) and current (I) The internal resistance value (R) of the battery 1 is detected by the following equation.
R = [open voltage (Vocv) −load voltage (Vccv)] / current (I)

  According to a third aspect of the present invention, in addition to the configuration of the second aspect, the detection circuit 8 detects the voltage (Vpre) across the precharge resistor 6 when the precharge switch 7 is on. The current (I) of the precharge resistor 6 is detected from the detected voltage (Vpre) and the resistance value (Rpre) of the precharge resistor 6.

  According to a fourth aspect of the present invention, in addition to the configuration of the second aspect, the detection circuit 8 detects the load voltage (Vccv) of the traveling battery 1 when the precharge switch 7 is on, The current (I) of the precharge resistor 6 is detected from the detected load voltage (Vccv) and the resistance value (Rpre) of the precharge resistor 6 to detect the internal resistance value (R) of the traveling battery (1).

  According to a fifth aspect of the present invention, in addition to the configuration of the first aspect of the present invention, the detection circuit 8 turns on the precharge switch 7 and charges the capacitor 13 (t), The internal resistance value (R) of the traveling battery (1) is detected from the capacitance (C).

  According to a sixth aspect of the present invention, in addition to the configuration of the first aspect, the control circuit 4 causes the deterioration of the traveling battery (1) from the internal resistance value (R) of the traveling battery (1). Determine the degree.

  The power supply device for a vehicle according to the present invention does not need to discharge the battery wastefully in order to detect the internal resistance value of the traveling battery. This is because the internal resistance value is detected using charging of the capacitor of the load. A power supply device for a vehicle precharges a capacitor prior to connecting a traveling battery to a load. This is to prevent contact of the contactor from being welded by a large instantaneous current of the capacitor. Since the power supply device of the present invention detects the internal resistance value of the battery for traveling by detecting the voltage and current when the capacitor is precharged, the battery is not discharged unnecessarily to detect the internal resistance value. .

  Further, the timing for detecting the internal resistance value is not specified in the traveling state of the vehicle, and the internal resistance value of the traveling battery can be detected whenever the ignition switch is turned on and the vehicle is traveling. Further, it is not necessary to provide a dedicated discharge resistor and a dedicated switch, although the traveling battery is discharged and the internal resistance value is detected. This is because the internal resistance value of the traveling battery is detected using a precharge resistor and a precharge switch for precharging the load capacitor. In particular, the resistance value of the precharge resistor is small, and the feature that a low-resistance internal resistance can be detected with high accuracy is realized. The reason why the resistance value of the precharge resistor is small is that the resistance value of the precharge resistor specifies the charging time of the capacitor and can be reduced to shorten the charging time of the capacitor. Furthermore, the power supply device of the present invention detects the voltage or current when precharging the capacitor, or detects the time when the capacitor is charged to a predetermined state, and detects the internal resistance from the detected voltage, current and time. Since the value is detected, the precharge circuit precharges the capacitor without affecting the precharge of the capacitor and without performing a dedicated control to detect the internal resistance value of the battery for driving. The internal resistance value of the battery can be detected. This realizes the feature that the internal resistance value of the traveling battery can be accurately detected without complicating the precharge circuit and the control circuit.

  Embodiments of the present invention will be described below with reference to the drawings. However, the following embodiment exemplifies a power supply device for a vehicle for embodying the technical idea of the present invention, and the present invention does not specify the power supply device as follows.

  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. 1 is mounted on a vehicle such as a hybrid car, a fuel cell vehicle, or an electric vehicle, and drives a motor 11 connected as a load 10 to drive the vehicle. A motor 11 serving as a load 10 of the traveling battery 1 is connected to the traveling battery 1 via an inverter 12. The inverter 12 converts the direct current of the traveling battery 1 into a three-phase alternating current, and controls the power supplied to the motor 11.

  The power supply device shown in FIG. 1 is connected to the traveling battery 1, the contactor 2 connected to the output side of the traveling battery 1 to switch the power supply to the load 10 on and off, and before the contactor 2 is switched on, A precharge circuit 3 that precharges the capacitor 13 and a control circuit 4 that controls the precharge circuit 3 and the contactor 2 to be turned on and off, and further includes a detection circuit 8 that detects the internal resistance value of the traveling battery. Prepare.

  The load 10 has a motor 11 connected to the output side of the inverter 12. The inverter 12 that is the load 10 has a large-capacity capacitor 13 connected in parallel. The capacitor 13 supplies power to the inverter 12 of the load 10 from both the traveling battery 1 and the contactor 2 in a state where the contactor 2 is turned on. In particular, large power is instantaneously supplied from the capacitor 13 to the inverter 12 of the load 10. The instantaneous power that can be supplied to the load 10 can be increased by connecting the capacitor 13 in parallel to the traveling battery 1. Since the instantaneous maximum power that can be supplied from the capacitor 13 to the inverter 12 of the load 10 is proportional to the capacitance, a capacitor having an extremely large capacitance of, for example, 4000 to 6000 μF is used. When the large-capacitance capacitor 13 in a discharged state is connected to the traveling battery 1 having a high output voltage, an extremely large charge current instantaneously flows. This is because the impedance of the capacitor 13 is extremely small.

  The traveling battery 1 drives a motor 11 that causes the vehicle to travel through an inverter 12. In order to supply a large amount of power to the motor 11, the traveling battery 1 has a high output voltage by connecting a large number of rechargeable cells 5 in series. As the unit cell 5, a nickel metal hydride battery or a lithium ion battery is used. However, any rechargeable battery such as a nickel cadmium battery can be used as the battery. 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 11. However, the power supply device can also connect a DC / DC converter (not shown) to the output side of the traveling battery, boost the voltage of the traveling battery, and supply power to the load. This power supply device can reduce the output voltage of the traveling battery by reducing the number of batteries connected in series. Therefore, the traveling battery can have an output voltage of 150 to 400V, for example.

  The precharge circuit 3 precharges the capacitor 13 of the load 10 with the ON signal input from the ignition switch 14 before the contactor 2 is switched on. The precharge circuit 3 precharges the capacitor 13 while limiting the charging current of the capacitor 13. The precharge circuit 3 has a precharge switch 7 and a precharge switch 7 connected in series. The precharge resistor 6 limits the precharge current of the capacitor 13 of the load 10. The precharge circuit 3 can reduce the precharge current by increasing the resistance value of the precharge resistor 6. For example, the precharge resistor 6 is a cement resistor of 10Ω and 30W. The precharge resistor 6 limits the peak charging current at which the traveling battery 1 with an output voltage of 400V charges the capacitor 13 to 40A. The precharge resistor 6 can increase the resistance value to reduce the maximum value of the precharge current. However, when the resistance value of the precharge resistor 6 is increased, the time for precharging the capacitor 13 becomes longer. This is because the precharge current becomes small. Further, the peak power consumption when the precharge resistor 6 precharges the capacitor 13 is in proportion to the square of the voltage of the traveling battery 1 and inversely proportional to the resistance value of the precharge resistor 6. Therefore, if the resistance value of the precharge resistor 6 is reduced, the current increases and the peak power consumption increases. The resistance value of the precharge resistor 6 is set to, for example, 5 to 20Ω, preferably 6 to 18Ω, and more preferably 6 to 15Ω in consideration of the precharge current, the precharge time, and the power consumption.

  The precharge resistor 6 is heated by Joule heat of a current for precharging the capacitor 13. The temperature at which the precharge resistor 6 is heated is lower when the W number, which is the allowable power, is increased, and is increased when the W number is decreased. A precharge resistor having a large W number is large and expensive. In particular, since the precharge resistor used for this type of application is as large as several tens of watts, it is very difficult to further increase the W number because it increases the space for arrangement. However, if the W number of the precharge resistor is reduced, the precharge resistor is heated to a high temperature and gives a thermal failure to surrounding members. Accordingly, the W number of the precharge resistor 6 is 20 to 50 W in consideration of the resistance value and the frequency at which the ignition switch 14 is continuously turned on.

  The precharge circuit 3 is connected in parallel to the contact of the contactor 2. In the illustrated power supply apparatus, contactors 2 are provided on both the plus side and the minus side, and the precharge circuit 3 is connected in parallel with the contact of the plus side contactor 2A. In this power supply device, the precharge circuit 3 precharges the capacitor 13 in a state in which the negative contactor 2B is turned on and the positive contactor 2A is turned off. When the capacitor 13 is precharged by the precharge circuit 3, the positive contactor 2A is switched from OFF to ON, and the precharge switch 7 of the precharge circuit 3 is switched OFF.

  The precharge circuit 3 turns on the precharge switch 7 to precharge the capacitor 13. The precharge switch 7 is a switch having a mechanical contact such as a relay. However, the precharge switch can also use semiconductor switching elements such as transistors and FETs. Since the precharge switch of the semiconductor switching element is not deteriorated like a contact, the life can be extended. Further, since it can be switched on and off at high speed in a very short time, the capacitor can be precharged while being switched on and off. The semiconductor switching element that switches on and off to precharge the capacitor is switched on in synchronization with the timing at which the control circuit detects the voltage and current. This is because the control circuit detects the internal resistance value of the traveling battery 1 from the detected voltage or current.

  Further, the semiconductor switching element can control the precharge current with a duty for switching on and off. That is, it is possible to reduce the precharge current by shortening the on time with respect to the off time, and conversely, increase the precharge current by increasing the on time with respect to the off time. The semiconductor switching element that controls the precharge current by changing the duty in this way can also precharge the capacitor while changing the duty. For example, at the beginning of precharging a capacitor, the duty can be reduced to limit the precharge current, and when the capacitor is precharged and the current decreases, the duty can be increased to increase the current. . This method can precharge the capacitor with less change in precharge current. The semiconductor switching element can be turned on / off with a predetermined duty by a control circuit.

  After the precharge circuit 3 precharges the capacitor 13, the control circuit 4 switches on the plus-side contactor 2 </ b> A that is controlled in parallel with the precharge circuit 3, thereby supplying power from the traveling battery 1 to the load 10. The state in which the vehicle can be supplied is set, that is, the vehicle 11 can be driven by driving the motor 11 with the traveling battery 1.

  Further, the control circuit 4 includes a detection circuit 8 that detects the internal resistance value (R) of the traveling battery 1 in a state in which the ignition switch 14 is turned on and the capacitor 13 is precharged.

Here, the traveling battery 1 has a large number of unit cells 5 connected in series, and as shown in FIG. 2, each unit cell 5 constituting the traveling battery 1 has an internal resistance 5a, The resistor 5a is also connected in series. Therefore, the internal resistance value (R) of the traveling battery 1 is the sum of the resistance values (R1, R2,... Rn) of the internal resistances 5a. Therefore, in the present specification, detecting the internal resistance value (R) of the traveling battery means detecting the sum of the resistance values of the internal resistances of a plurality of unit cells constituting the traveling battery. 1, 3, and 4, the internal resistance of each unit cell 5 constituting the traveling battery 1 is omitted, and the combined resistance of these internal resistances is represented as the internal resistance 1 a of the traveling battery 1. ing.
However, in the power supply device of the present invention, it is not always necessary to configure one traveling battery with a plurality of unit cells, and a plurality of traveling batteries are configured with one to a plurality of unit cells, and each traveling battery is It is also possible to detect the internal resistance value for each traveling battery by detecting the voltage. As described above, the structure in which the internal resistance value is detected by being divided into a plurality of traveling batteries can determine the deterioration degree of the battery for each divided traveling battery.

FIG. 3 and FIG. 4 show the operation principle by which the detection circuit 8 detects the internal resistance value of the traveling battery 1. The detection circuit 8 detects the internal resistance value (R) from the voltage and current of the traveling battery 1. The internal resistance value (R) of the traveling battery 1 is detected by the following equation.
R = [open voltage (Vocv) −load voltage (Vccv)] / current (I)

The open circuit voltage (Vocv) of the traveling battery 1 is detected in a state where the current of the traveling battery 1 is cut off by turning off the precharge switch 7 as shown in FIG. As shown in FIG. 4, the load voltage (Vccv) of the traveling battery 1 is detected in a state where the precharge switch 7 is turned on. The current (I) of the traveling battery 1 is detected by the current sensor 9. Further, the current (I) of the battery 1 for traveling can be detected by detecting the voltage (Vpre) of the precharge resistor 6. The current (I) of the traveling battery 1 becomes the current of the precharge resistor 6, and the voltage (Vpre) of the precharge resistor 6 becomes the product of the resistance value (Rpre) of the precharge resistor 6 and the current (I). (I) can be detected by the following equation.
Current (I) = Voltage (Vpre) / Precharge resistance value (Rpre)

Therefore, the internal resistance value (R) of the traveling battery 1 is detected by the following equation.
R = [open voltage (Vocv) −load voltage (Vccv)] / current (I)
= [Open circuit voltage (Vocv)-Load voltage (Vccv)]
× Precharge resistance value (Rpre) / Voltage (Vpre)

  The detection circuit 8 that detects the internal resistance value (R) of the traveling battery 1 using this equation switches the precharge switch 7 to ON, and then loads the load voltage (at a specific timing when the current flows through the precharge resistor 6). The internal resistance value (R) of the traveling battery 1 is detected by detecting Vccv) and the voltage (Vpre) of the precharge resistor 6 at the same timing.

  When the control circuit 4 switches the precharge switch 7 on, a current for precharging the capacitor 13 flows. As shown in FIG. 5, the precharge current of the capacitor 13 is initially large and decreases as the capacitor 13 is charged. At the moment when the precharge switch 7 is turned on, the voltage across the capacitor 13 is 0 V in a state where the capacitor 13 is not charged. In other words, the capacitor 13 is short-circuited in terms of DC, and the capacitor passes over time. As 13 is charged, the voltage across the capacitor gradually increases. The load voltage (Vccv) at the moment when the precharge switch 7 is turned on becomes the minimum voltage (Vmin), and the current (I) becomes the maximum peak current (Imax).

The peak current (Imax) is expressed by the following formula.
Peak current (Imax) = minimum voltage (Vmin) / resistance value of precharge resistor (Rpre)
Therefore, the internal resistance value (R) of the traveling battery 1 is detected by the following equation.
R = [open voltage (Vocv) −load voltage (Vccv)] / current (I)
= [Open voltage (Vocv)-Minimum voltage (Vmin)] / Peak current (Imax)
= [Open voltage (Vocv)-Minimum voltage (Vmin)]
× Precharge resistance value (Rpre) / Minimum voltage (Vmin)

Further, the detection circuit 8 can detect the internal resistance value of the traveling battery 1 by detecting the time until the voltage becomes a predetermined voltage from the voltage of the capacitor 13 that changes as shown in FIG. .
FIG. 6 shows a state in which the charge Q (t) charged in the capacitor 13 changes when the precharge switch 7 is turned on. The charge Q (t) charged in the capacitor 13 changes as shown by the following equation.
Charge Q (t) = C × Vocv × [1-exp {t / [(R + Rpre) × C]}]
In this equation, C is the capacitance of the capacitor 13 connected to the load, t is the time that elapses after the precharge switch 7 is turned on, R is the internal resistance value of the traveling battery 1, and Rpre is the precharge resistance. Resistance value.
If τ = (R + Rpre) × C,
Charge Q (τ) = C × Vocv × [1-1 / e] = 0.63212 × C × Vocv.
Since the time (τ) is until the load voltage (Vccv) becomes 0.63212 times the open circuit voltage (Vocv), this time (τ) is detected, and the internal resistance value of the traveling battery 1 is calculated from the following equation. (R) is detected.
R = (τ / C) −Rpre

  The power supply device for a vehicle is configured as a traveling battery 1 by connecting a large number of rechargeable cells 5 in series. This power supply device has a connection resistor 15 at a connection portion such as a bus bar for connecting the unit cells 5 in series. As shown in the equivalent circuit diagram of FIG. 7, this power supply device has a connection resistor 15 connected in series with an internal resistance value 1 a of the traveling battery 1, and a combined resistance of the internal resistance value (R ) Is detected. However, since the resistance value (RK) of the connection resistor 15 is a constant and known value, the resistance value (RK) of the connection resistor 15 is subtracted from the internal resistance value (R) detected from the above equation, and the running The internal resistance value (RE) of the battery 1 is obtained. Therefore, in the present invention, the internal resistance value (R) including the resistance value (RK) of the connection resistance 15 is detected or the resistance value (RK) of the connection resistance 15 is subtracted as the internal resistance value of the traveling battery 1. The internal resistance value (RE) can be detected.

  The control circuit 4 can determine the degree of deterioration from the internal resistance value (R) of the traveling battery 1 calculated from the above formula. The control circuit 4 stores a function or table that specifies the degree of deterioration from the internal resistance value (R) of the traveling battery 1, and determines the degree of deterioration of the traveling battery 1 from the stored function or table. In order to determine the degree of deterioration from the internal resistance value (R), the minimum internal resistance value (Rmin) that is the internal resistance value of the new traveling battery and the maximum internal resistance value that is the internal resistance value of the traveling battery whose life has expired. (Rmax) is measured, and when the internal resistance value (R) of the traveling battery reaches the maximum internal resistance (Rmax), it is assumed that the battery is completely deteriorated and the deterioration degree is 0%. As for the deterioration degree of the battery 1 for traveling, the deterioration degree in the new state is 100%, and the deterioration degree in the completely deteriorated state is 0%. FIG. 8 illustrates a function used by the control circuit 4 to determine the degree of deterioration from the internal resistance value of the traveling battery 1. In this figure, the degree of deterioration is linearly changed with respect to the internal resistance value, but the degree of deterioration with respect to the internal resistance value is not necessarily changed linearly. When determining the degree of deterioration of the traveling battery from the internal resistance value, the control circuit 4 performs control to limit the current and voltage for charging / discharging the traveling battery based on the degree of deterioration, or the determined traveling battery A signal indicating the degree of deterioration is output to the outside.

  The contactor 2 is a relay having a mechanically movable contact. The contactor 2 keeps the plus-side contactor 2A off and switches on only the minus-side contactor 2B. In this state, the precharge circuit 3 precharges the capacitor 13. After the capacitor 13 is precharged, the plus-side contactor 2A is switched from OFF to ON, and the traveling battery 1 is connected to the load 10. Thereafter, the precharge switch 7 of the precharge circuit 3 is switched off. When switching on the contactor 2 in the on state, both connections are simultaneously turned off.

  The above power supply apparatus precharges the capacitor 13 and detects the internal resistance value (R) of the battery 1 for traveling in the flowchart of FIG.

[Step of n = 1]
It is determined whether or not an ON signal is input from the ignition switch 14 to the control circuit 4. This step is looped until the ON signal of the ignition switch 14 is input.

[Step of n = 2]
When an ON signal is input from the ignition switch 14 to the control circuit 4, the detection circuit 8 detects the open circuit voltage (Vocv) of the traveling battery 1. The open circuit voltage (Vocv) of the traveling battery 1 is detected in a state where the current of the traveling battery 1 is cut off by turning off the precharge switch 7 as shown in FIG.

[Step n = 3]
The control circuit 4 controls the contactor 2 and the precharge switch 7 to start precharging. The control circuit 4 keeps one contactor (minus-side contactor 2B in FIG. 1) on and the other contactor (plus-side contactor 2A in FIG. 1) off, and is connected in parallel with the off-contactor 2. The precharge switch 7 of the precharge circuit 3 is turned on. In this state, the traveling battery 1 is connected to the capacitor 13 via the precharge resistor 6 to precharge the capacitor 13. The precharge resistor 6 precharges the capacitor 13 with the traveling battery 1 while limiting the precharge current.

[Step n = 4]
When the precharge is started, the detection circuit 8 detects the load voltage (Vccv) of the traveling battery 1 and the current (I) of the traveling battery 1. The load voltage (Vccv) and current (I) of the traveling battery 1 are detected with the precharge switch 7 turned on, as shown in FIG. The current (I) of the traveling battery 1 is detected by the current sensor 9. However, the current (I) of the traveling battery 1 can be detected from the voltage (Vpre) of the precharge resistor 6 and the resistance value (Rpre) of the precharge resistor 6 by detecting the voltage (Vpre) of the precharge resistor 6. .
When the precharge switch 6 is turned on and the precharge is started, the precharge current of the capacitor 13 is initially large as shown in FIG. 5 and decreases as the capacitor 13 is charged. Further, the load voltage (Vccv) of the traveling battery 1 gradually increases as the capacitor 13 is charged. Therefore, the load voltage (Vccv) and the current (I) of the traveling battery 1 are the same in synchronization at a specific timing when the current flows through the precharge resistor 6 after the precharge switch 7 is turned on. Is detected. As for the load voltage (Vccv) and current (I) of the battery 1 for traveling, for example, the minimum voltage (Vmin) and the maximum peak current (Imax) at the moment when the precharge switch 7 is switched on can be detected.

[Step n = 5]
In this step, the detection circuit 8 detects the internal resistance value (R) of the traveling battery 1. The detection circuit 8 detects the internal resistance value (R) of the traveling battery 1 from the detected open circuit voltage (Vocv), load voltage (Vccv), and current (I) based on the following equation.
R = [open voltage (Vocv) −load voltage (Vccv)] / current (I)
However, the detection circuit 8 detects the internal resistance value (R) of the battery 1 for traveling from the time (t) for charging the capacitor 13 by turning on the precharge switch 7 and the capacitance (C) of the capacitor 13. You can also. The detection circuit 8 detects the time until the voltage of the capacitor 13 that changes as shown in FIG. 6 reaches a predetermined voltage, and detects the internal resistance value (R) of the battery 1 for traveling. The detection circuit 8 detects the time (τ) until the load voltage (Vccv) becomes 0.63212 times the open circuit voltage (Vocv), and calculates the internal resistance value (R) of the battery 1 for traveling from the following equation. To detect.
R = (τ / C) −Rpre

[Step n = 6]
In this step, it is determined whether or not the precharge of the capacitor 13 is completed. Completion of the precharge is detected when the precharge current is reduced to the set current, or is detected when the precharge switch 7 is turned on. This step is looped until the precharge is completed.
[Step n = 7]
When the precharge is completed, the positive-side contactor 2A is turned on, and then the precharge switch 7 is turned off.

It is a schematic block diagram of the power supply device for vehicles concerning one Example of the present invention. It is a circuit diagram of the battery for driving | running | working. It is a principle figure which shows the state which detects the open circuit voltage (Vocv) with the power supply device for vehicles shown in FIG. It is a principle figure which shows the state which detects the load voltage (Vccv) in the power supply device for vehicles shown in FIG. It is a graph which shows the state in which the precharge electric current and load voltage when precharging a capacitor change with time. It is a graph which shows the state from which the electric charge charged to a capacitor changes with time. It is an equivalent circuit diagram which shows the connection resistance connected in series with the internal resistance of the battery for driving | running | working. It is a figure which shows an example of the function which discriminate | determines a deterioration degree from the internal resistance of the battery for driving | running | working. It is a flowchart in which the power supply device for vehicles concerning one Example of this invention detects the internal resistance value of the battery for driving | running | working.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Battery for driving | running | working 1a ... Internal resistance 2 ... Contactor 2A ... Positive side contactor
2B ... Negative contactor 3 ... Precharge circuit 4 ... Control circuit 5 ... Unit cell 5a ... Internal resistor 6 ... Precharge resistor 7 ... Precharge switch 8 ... Detection circuit 9 ... Current sensor 10 ... Load 11 ... Motor 12 ... Inverter 13 ... Capacitor 14 ... Ignition switch 15 ... Connection resistance

Claims (6)

A battery (1) that can be charged, a contactor (2) that connects the battery (1) to the load (10), and an ignition switch (14) connected in parallel with the contactor (2). A precharge circuit (3) for precharging the capacitor (13) of the load (10) with a signal input from the control circuit, and a control circuit (4) for controlling the precharge circuit (3) and the contactor (2). A power supply device for a vehicle,
The precharge circuit (3) includes a precharge resistor (6) for limiting a precharge current for charging the capacitor (13), and a precharge switch (7) connected in series to the precharge resistor (6). With
The control circuit (4) turns on the precharge switch (7) and passes the charging current of the capacitor (13) through the precharge resistor (6) to detect the internal resistance value (R) of the battery (1) for traveling. A power supply device for a vehicle having a built-in detection circuit (8). The detection circuit (8) detects the open voltage (Vocv) of the traveling battery (1) when the precharge switch (7) is off and the load voltage of the traveling battery (1) when the precharge switch (7) is on. (Vccv) and the current (I) of the precharge resistor (6) are detected, and the internal resistance value (R) of the traveling battery (1) is determined from the open circuit voltage (Vocv), the load voltage (Vccv) and the current (I). The vehicle power supply device according to claim 1, which is detected by the following equation.
R = [open voltage (Vocv) −load voltage (Vccv)] / current (I)   The detection circuit (8) detects the voltage (Vpre) across the precharge resistor (6) when the precharge switch (7) is on, and the detected voltage (Vpre) and the resistance value of the precharge resistor (6) The power supply device for a vehicle according to claim 2, wherein the current (I) of the precharge resistor (6) is detected from (Rpre).   The detection circuit (8) detects the load voltage (Vccv) of the traveling battery 1 when the precharge switch (7) is on, and the detected load voltage (Vccv) and the resistance value (Rpre) of the precharge resistor (6). The vehicle power supply device according to claim 2, wherein the internal resistance value (R) of the battery 1 for traveling is detected by detecting the current (I) of the precharge resistor (6).   The detection circuit (8) turns on the precharge switch (7) and charges the capacitor (13) (t) and the capacitance (C) of the capacitor (13) to determine the inside of the traveling battery (1). The power supply device for vehicles described in Claim 1 which detects resistance value (R).   The power supply device for a vehicle according to claim 1, wherein the control circuit (4) determines the degree of deterioration of the traveling battery (1) from the internal resistance value (R) of the traveling battery (1).

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