JP2005269742A - Power source device for vehicle and switching method of contactor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To safely switch a contactor to on by detecting exactly a precharge while preventing effectively a precharge resistor from being damaged by fire by a short circuit, etc. of a load. <P>SOLUTION: A power source device for a vehicle includes the contactor 2 for controlling a power supply to the load 11, a precharge circuit 3 having a precharge resistor 6 and a precharge switch 7, and a control circuit 4 for controlling on and off of the precharge switch 7 and the contactor 2. After the precharge circuit 3 precharges the capacitor 13, the contactor 2 is switched to on. The control circuit 4 compares the current of a running battery 1 detected by a current detector circuit 8 with a set current in the state that the time of the start timer is up. Further, a voltage difference between the primary side and the secondary side of the contactor 2 detected by the voltage detector circuit 9 with a set voltage, and the contactor 2 is switched to on in the state that the current of the running battery 1 is smaller than the set current and the voltage difference is lower than the set voltage. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention provides a vehicle power supply device that switches on a contactor with a precharge circuit in a state where a large-capacity capacitor connected in parallel to a load of a running battery mounted on the vehicle is precharged, The present invention relates to a contactor switching method.

  A vehicle power supply device supplies power to a load having a large-capacity capacitor connected in parallel. This power supply device has a contactor connected to the output side, and supplies power to the load via the contactor. The contactor is switched off in the event of an abnormality to shut off the output. Further, the output is cut off when the vehicle is not used, for example, when the ignition switch of the automobile is turned off. Also, when the car collides, the contactor is turned off to shut off the output and improve safety.

When the contactor is switched on, the traveling battery charges a large capacity capacitor. At this time, a very large charge current flows instantaneously. The large charge current damages the contactor contacts. In particular, the contactor contact may be welded by a large charge current. When the contacts are welded, the contactor can no longer be switched off, preventing the travel battery from being disconnected from the load. In order to prevent this problem, a power supply device having a precharge circuit for precharging the capacitor before switching the contactor on has been developed (see Patent Document 1).
JP 2001-128305 A

  Japanese Patent Application Laid-Open No. 2004-228561 describes a power supply device including a precharge circuit. The precharge circuit is provided between the traveling battery and the load, and precharges the capacitor while limiting the current. The precharge circuit includes a precharge resistor for limiting current and a precharge switch connected in series to the precharge resistor. The precharge circuit is connected in parallel with the contactor. The precharge circuit turns on the precharge switch to precharge the capacitor connected to the load. When the capacitor is precharged, the voltage difference between the primary and secondary sides of the contactor decreases. When the voltage difference becomes lower than the set voltage, the contactor is switched on and the traveling battery is connected to the load. After switching the contactor on, the precharge switch is switched off.

  However, in the precharge circuit of this structure, for example, when the load is short-circuited or very low resistance or close to a short circuit, a large current flows through the precharge resistor for a long time. The harmful effect of burning out occurs. The precharge resistor is used in a state where a precharge current flows for a short time in a normal use state. Therefore, a capacity that can withstand this use condition, that is, a wattage resistance is used. Although the precharge current is a large current, a short energization time reduces the temperature rise of the precharge resistor. For this reason, the precharge resistor having a wattage capable of withstanding a short precharge current is used. In other words, the precharge resistor has a wattage that can withstand the instantaneous precharge current. When a large current continuously flows through the precharge resistor, the precharge resistor continuously generates a large Joule heat, which overheats and burns out the precharge resistor. That is, there is a drawback that the precharge resistor is burned out before the completion of the precharge is detected.

  In particular, power supply devices mounted on vehicles are used in harsh environments where the external conditions such as temperature and humidity are severe and are subject to vibrations and shocks. Extremely difficult. For this reason, it is important to detect various faults as quickly as possible so that the faults do not cause other parts to fail.

  The present invention was developed for the purpose of realizing this, and an important object of the present invention is to effectively prevent the precharge resistor from being burned out in a load short circuit or a low resistance state. An object of the present invention is to provide a power supply device for a vehicle that can reliably detect precharge of a capacitor and can safely turn on the contactor, and a contactor switching method.

  The power supply device for a vehicle according to the present invention is connected to the output side of the traveling battery 1 and controls a power supply to a load 11 connected in parallel with a capacitor 13, and the contactor 2 is turned off. A precharge circuit 3 having a precharge resistor 6 and a precharge switch 7 for limiting the precharge current of the capacitor 13 of the load 11 when switching on, and a control for controlling on / off of the precharge switch 7 and the contactor 2 Circuit 4. This power supply device switches the contactor 2 on after the precharge circuit 3 precharges the capacitor 13.

  Furthermore, the power supply device according to claim 1 of the present invention is configured such that the control circuit 4 starts counting after the precharge switch 7 is turned on, and the battery for traveling is in a state in which the start timer expires. 1 is provided with a current detection circuit 8 that detects a current flowing through 1 and a voltage detection circuit 9 that detects a voltage difference between the primary side and the secondary side of the contactor 2. The control circuit 4 compares the current of the traveling battery 1 detected by the current detection circuit 8 with the set current in a state where the start timer expires, and then the primary side of the contactor 2 detected by the voltage detection circuit 9 The voltage difference with the secondary side is compared with the set voltage, and the contactor 2 is switched on in a state where the current of the traveling battery 1 is smaller than the set current and the voltage difference is lower than the set voltage.

  Furthermore, the power supply device according to claim 2 of the present invention is configured so that the control circuit 4 includes a start timer that starts counting after the precharge switch 7 is switched on, and the contactor 2 A voltage detection circuit 9 that detects a voltage difference between the primary side and the secondary side, and a current detection circuit 8 that detects a current flowing through the traveling battery 1 are provided. The control circuit 4 compares the voltage difference detected by the voltage detection circuit 9 with the set voltage while the start timer expires, and further compares the current of the traveling battery 1 detected by the current detection circuit 8 with the set current. Then, the contactor 2 is switched on in a state where the voltage difference is lower than the set voltage and the current of the traveling battery 1 is smaller than the set current.

  Furthermore, the power supply device according to claim 3 of the present invention is configured such that the control circuit 4 starts counting after the precharge switch 7 is turned on, and the battery for traveling is in a state in which the start timer expires. 1 is provided with a current detection circuit 8 that detects a current flowing through the current. The control circuit 4 compares the first detection current detected by the current detection circuit 8 with the first set current in a state where the start timer expires, and then the second detection current detected by the current detection circuit 8 is The contactor 2 is switched on in a state where the first detection current is smaller than the first setting current and the second detection current is smaller than the second setting current as compared with the second setting current smaller than the one setting current.

  A power supply device for a vehicle according to a fourth aspect of the present invention is the power supply device according to the first aspect, wherein the control circuit 4 includes an intermediate timer. This intermediate timer detects the current of the traveling battery 1 by the current detection circuit 8, and starts counting when the current is smaller than the set current. In the control circuit 4, the voltage detection circuit 9 detects the voltage of the precharge resistor 6 and compares it with the set voltage in a state where the intermediate timer expires.

  The power supply device for a vehicle according to claim 5 of the present invention is the power supply device according to claim 2, wherein the control circuit 4 includes an intermediate timer. The intermediate timer starts counting when the voltage detection circuit 9 detects the voltage of the precharge resistor 6 and the voltage is lower than the set voltage. In the control circuit 4, the current detection circuit 8 detects the current of the traveling battery 1 and compares it with the set current in a state where the intermediate timer expires.

  A power supply device for a vehicle according to a sixth aspect of the present invention is the power supply device according to the third aspect, wherein the control circuit 4 includes an intermediate timer. The intermediate timer starts counting when the first detection current detected by the current detection circuit 8 is smaller than the first set current. In the control circuit 4, the current detection circuit 8 detects the second detection current and compares it with the second set current in a state where the intermediate timer expires.

  A power supply device for a vehicle according to a seventh aspect of the present invention is the power supply device according to the first aspect, wherein the control circuit 4 includes a precharge timer. This precharge timer specifies the time during which the voltage detection circuit 9 detects the voltage difference. When the voltage difference detected by the voltage detection circuit 9 does not drop to the set voltage during the set time of the precharge timer, the power supply circuit switches off the precharge switch 7 and interrupts the precharge.

  A power supply device for a vehicle according to an eighth aspect of the present invention is the power supply device according to the second aspect, wherein the control circuit 4 includes a precharge timer. The precharge timer specifies the time for detecting the current of the traveling battery 1. If the current of the running battery 1 detected by the current detection circuit 8 does not drop to the set current during the set time of the precharge timer, the power supply device switches off the precharge circuit 3 and interrupts the precharge. .

  A power supply device for a vehicle according to a ninth aspect of the present invention is the power supply device according to the third aspect, wherein the control circuit 4 includes a precharge timer. This precharge timer specifies the time during which the current detection circuit 8 detects the second detection current of the traveling battery 1. If the second detection current detected by the current detection circuit 8 does not decrease to the second set current during the set time of the precharge timer, the power supply device switches off the precharge circuit 3 and interrupts the precharge. .

  The contactor switching method for a vehicle power supply apparatus according to the present invention includes a contactor 2 connected to the output side of a traveling battery 1 and controlling power supply to a load 11 connected in parallel with a capacitor 13, and a contactor. 2 is switched from OFF to ON, a precharge circuit 3 having a precharge resistor 6 and a precharge switch 7 for limiting the precharge current of the capacitor 13 of the load 11, and the precharge switch 7 and the contactor 2 are turned on / off. This is a method of switching a contactor 2 of a power supply device including a control circuit 4 to be controlled. In this switching method, the precharge circuit 3 precharges the capacitor 13 connected in parallel to the load 11 and then switches the contactor 2 on.

  Furthermore, the contactor switching method according to claim 10 of the present invention starts the count of the start timer when the precharge switch 7 is switched on, and detects the current flowing through the traveling battery 1 when the start timer expires. Then, the voltage difference between the primary side and the secondary side of the contactor 2 is detected. After the start timer expires, the current of the running battery 1 detected by the current detection circuit 8 is compared with the set current, and then the voltage difference detected by the voltage detection circuit 9 is further compared with the set voltage. The contactor 2 is switched on in a state where the current of the traveling battery 1 is smaller than the set current and the voltage difference of the precharge resistor 6 is lower than the set voltage.

  Furthermore, the contactor switching method according to claim 11 of the present invention starts counting the start timer when the precharge switch 7 is turned on, and when the start timer expires, the contactor 2 on the primary side and the secondary side are counted. The voltage difference from the side is detected, and then the current flowing through the traveling battery 1 is detected. After the start timer expires, the voltage difference detected by the voltage detection circuit 9 is compared with the set voltage, and then the current of the traveling battery 1 detected by the current detection circuit 8 is further compared with the set current. In a state where the voltage difference is lower than the set voltage and the current of the traveling battery 1 is smaller than the set current, the contactor 2 is switched on.

  Further, according to the contactor switching method of the twelfth aspect of the present invention, when the precharge switch 7 is switched on, the start timer starts counting, and when the start timer expires, the current flowing in the traveling battery 1 is detected. To do. After the start timer expires, the first detection current detected by the current detection circuit 8 is compared with the first set current, and then the second detection current detected by the current detection circuit 8 is further compared with the second set current. To do. In a state where the first detection current is smaller than the first set current and the second detection current is smaller than the second set current, the contactor 2 is switched on.

  The vehicle power supply device and the contactor switching method of the present invention reliably detect the precharge of the capacitor while effectively preventing the precharge resistor from burning out due to a short circuit of the load or a low resistance state. It has the feature that the contactor can be switched on safely. The power supply device according to claims 1 and 2 of the present invention and the contactor switching method according to claims 10 and 11 are configured such that when a predetermined time elapses after the precharge switch is turned on, This is because the primary side and the secondary side of the contactor are compared with the set values, and the contactor is switched on in a state where the current of the battery for traveling is smaller than the set current and the voltage difference is lower than the set voltage. . Furthermore, in the method for switching between the power supply device according to claim 3 and the contactor according to claim 12 of the present invention, the current flowing through the traveling battery is set to a time difference after a predetermined time has elapsed since the precharge switch was turned on. Provided, detected, and compared with the set current, in a state where the first detected current is smaller than the first set current and the second detected current is smaller than the second set current smaller than the first set current. This is because the contactor is switched on.

  Therefore, according to the present invention, even when the capacitor is not precharged due to a short circuit of the load and the current flowing through the precharge resistor does not decrease, it is ensured that a large current flows through the precharge resistor for a long time. Therefore, it is possible to effectively prevent the precharge resistor from being burned out due to the large current, and to reliably detect the precharge of the capacitor and to switch the contactor safely.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment described below exemplifies a switching method between a power supply device and a contactor for a vehicle for embodying the technical idea of the present invention, and the present invention describes a switching method between the power supply device and the contactor as follows. Not specified.

  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 hybrid car or mounted on an electric vehicle, and drives a motor 12 connected as a load 11 to drive the vehicle. The power supply device of this figure is connected to the traveling battery 1, the contactor 2 connected to the output side of the traveling battery 1 and controlling the power supply to the load 11, and the loader prior to switching the contactor 2 on. 11 includes a precharge circuit 3 for precharging the capacitor 13 and a control circuit 4 for controlling the precharge circuit 3 and the contactor 2.

  The load 11 has a large capacity capacitor 13 connected in parallel. The capacitor 13 supplies power to the load 11 from both the traveling battery 1 and the contactor 2 in a state where the contactor 2 is switched on. In particular, a large power is instantaneously supplied from the capacitor 13 to the load 11. For this reason, the instantaneous electric power which can be supplied to the load 11 can be enlarged by connecting the capacitor | condenser 13 in parallel with the battery 1 for driving | running | working. Since the electric power that can be supplied from the capacitor 13 to the load 11 is proportional to the capacitance, a capacitor having an extremely large capacitance of, for example, 4000 to 6000 μF is used. When the large-capacity 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 12 that causes the vehicle to travel. The traveling battery 1 has a large number of secondary batteries 5 connected in series to increase the output voltage so that a large amount of power can be supplied to the motor 12. As the secondary battery 5, a nickel metal hydride battery or a lithium ion secondary battery is used. However, any rechargeable battery such as a nickel cadmium battery can be used as the secondary battery. The traveling battery 1 has an output voltage as high as 300 to 400 V, for example, so that large electric power can be supplied to the motor 12. 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 battery for traveling by reducing the number of secondary 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 while limiting the current. The precharge circuit 3 has a precharge resistor 6 and a precharge switch 7 connected in series. The precharge resistor 6 limits the precharge current of the capacitor 13 of the load 11. The precharge circuit 3 can reduce the precharge current by increasing the electrical resistance of the precharge resistor 6. For example, in a power supply device in which the precharge resistor 6 is 10Ω and the output voltage of the traveling battery 1 is 400 V, the maximum value of the precharge current is 40A. The precharge resistor 6 can be increased to reduce the maximum value of the precharge current. However, as the precharge resistor 6 increases, the time for precharging the capacitor 13 increases. This is because the precharge current becomes small. The electric resistance 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 and the precharge time.

  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. This power supply device precharges the capacitor 13 by the precharge circuit 3 in a state where the negative contactor 2B is switched on. When the capacitor 13 is precharged by the precharge circuit 3, the positive contactor 2A is switched 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, semiconductor switching elements such as transistors and FETs can also be used for the precharge switch.

  The contactor 2 is a relay having a mechanically movable contact. The contactor 2 keeps the first contact 2a (positive side contact in the figure) off and switches on only the second contact 2b (negative side contact in the figure). In this state, the capacitor 13 is precharged by the precharge circuit 3. After the capacitor 13 is precharged, the first contact 2 a is switched from OFF to ON, and the traveling battery 1 is connected to the load 11. Thereafter, the precharge switch 7 of the precharge circuit 3 is switched off. When switching on the contactor 2 in the on state, both contacts are simultaneously turned off.

  The control circuit 4 includes a start timer (not shown) for specifying the timing for detecting the current or voltage after the set time has elapsed after the start of precharging, and the current detection for detecting the current flowing through the traveling battery 1. A circuit 8 and a voltage detection circuit 9 that detects a voltage difference between the primary side voltage (Vt) and the secondary side voltage (Vi) with respect to the contactor 2 are provided. At the timing when the capacitor 13 is precharged, the current flowing through the traveling battery 1 is the same as the current of the precharge resistor 6. Note that the current detection circuit 8 may be installed on the primary side or in the traveling battery, instead of the secondary side as shown in FIG.

  The start timer specifies the timing of detecting the current of the traveling battery 1 or detecting the voltage across the precharge resistor 6 after the start of precharging. Therefore, the start timer starts counting when the precharge circuit 3 starts precharging, that is, when the precharge switch 7 is turned on. At the timing when the start timer expires, the control circuit 4 detects the current of the traveling battery 1 with the current detection circuit 8 or detects the voltage difference between the primary side and the secondary side with the voltage detection circuit 9. The set time of the start timer is set to a time during which the precharge current becomes a current that decreases from the peak current, for example, 50 msec, even if a short current flows through the precharge resistor 6. However, the set time of the start timer can be set to 20 to 200 msec, preferably 30 to 150 msec, and more preferably 30 to 100 msec.

  The current detection circuit 8 detects the current of the traveling battery 1. In the illustrated power supply apparatus, a current detection circuit 8 is connected to the output side of the contactor 2, but the current detection circuit is between the traveling battery 1 and the output terminal 10 and in a state where the capacitor 13 is precharged. It is connected to a position where the current flowing through the traveling battery 1 and the precharge resistor 6 can be detected. The current detection circuit 8 detects the leakage magnetic flux and detects the current, or detects the current by detecting the voltage of the precharge resistor. Further, although not shown, a current detection resistor having a very small electric resistance can be connected between the contactor and the output terminal, and the voltage of this current detection resistor can be detected to detect the current.

  The control circuit 4 further includes a voltage detection circuit 9 that detects a voltage difference between the primary side and the secondary side of the contactor 2. The voltage detection circuit 9 shown in the figure detects the primary side voltage (Vt) and the secondary side voltage (Vi) of the contactor 2, and detects the voltage difference between the primary side and the secondary side.

  The control circuit 4 compares the detection current detected by the current detection circuit 8 with the set current to determine whether the capacitor 13 is normally precharged or whether a current larger than the precharge of the capacitor 13 is flowing. judge. Therefore, the set current stored by the control circuit 4 is set to be larger than the normal precharge current at a predetermined time in the fully discharged capacitor 13 as shown in FIG. In the flowchart of FIG. 2, the set current is 15A. In a normal state, the precharge current of the capacitor 13 decreases with time as shown in FIG. This figure shows a state where the precharge switch 7 is turned on and the current decreases. When the load 11 is short-circuited or close to a short-circuit and an excessive current flows, the current flowing through the traveling battery 1 and the precharge resistor 6 becomes larger than this current. Therefore, as shown in FIG. 3, the set current is set larger than the precharge current of the capacitor 13 at a predetermined time. Since the precharge current decreases with time, the set current needs to change with time. In FIG. 3, the set current after 50 msec after turning on the precharge switch 7 is 15A.

  Although not shown, the power supply device of the present invention can detect an excessive current with the voltage of the precharge resistor 6. This power supply device detects an excessive current flowing through the load 11 by comparing an excessive voltage with a set voltage.

  Further, the control circuit 4 shown in FIG. 1 also includes an intermediate timer (not shown). In the intermediate timer, when the start timer expires, the current detection circuit 8 detects the current of the running battery 1 and starts counting when the current is smaller than the set current. The voltage detection circuit 9 detects the voltage of the precharge resistor 6 and compares it with the set voltage. That is, after the current detection circuit 8 detects that no overcurrent flows in the battery 1 for traveling, the time for the voltage detection circuit 9 to start detecting the voltage is detected in order to detect the completion of the precharge.

  When the start timer expires, the power supply device of the present invention can detect the voltage of the precharge resistor 6 first, and then detect the current of the traveling battery 1 to detect the completion of the precharge. The intermediate timer of this power supply device detects when the start timer expires and the voltage detection circuit 9 detects the voltage of the precharge resistor 6 to detect that the voltage is lower than the set voltage and no overcurrent flows. Start counting. When the intermediate timer expires, the current detection circuit 8 detects the current of the traveling battery 1 and detects the completion of the precharge as compared with the set current. This intermediate timer detects the current for the current detection circuit 8 to detect the completion of precharge after the voltage detection circuit 9 detects the voltage of the precharge resistor 6 and detects that no overcurrent is flowing. Specify the time to start.

  The set time of the intermediate timer is set to 250 msec, for example. However, the setting time of the intermediate timer is set to 50 to 500 msec, preferably 60 to 400 msec, and more preferably 100 to 350 msec. If the set time of the intermediate timer is too long, the detection of the precharge of the capacitor 13 is delayed. Conversely, if the set time is too short, it is necessary to detect the precharge from the timing when the capacitor 13 is not sufficiently precharged. The set time of the precharge timer is set in the above-described range so that the precharge of the capacitor 13 is detected quickly and the precharge is not detected from an early timing.

  The power supply device provided with the intermediate timer starts detecting whether or not the capacitor 13 has completed the precharge after a lapse of a certain time after detecting the overcurrent. The power supply apparatus of the present invention does not necessarily require an intermediate timer. The power supply device without the intermediate timer detects the overcurrent when the start timer expires, and when it is determined that the current is not an overcurrent, it immediately starts detecting the completion of the precharge of the capacitor 13.

  Further, the control circuit 4 includes a precharge timer (not shown). The precharge timer specifies a time period for detecting the precharge of the capacitor 13. When the precharge of the capacitor 13 is detected within the set time of the precharge timer, the contactor 2 is switched on. If the precharge of the capacitor 13 is not detected within the set time of the precharge timer, the precharge switch 7 is turned off and the precharge is stopped as a precharge error.

  In the flowchart of FIG. 2, the precharge timer setting time is 600 msec. The precharge timer starts counting from the start of detection of the voltage of the precharge resistor 6 and times up when 600 msec elapses. The set time of the precharge timer is set to be longer than the time during which the fully discharged capacitor 13 can be precharged by the precharge resistor 6. That is, the set time is specified so that normal precharge of the capacitor 13 is completed within the set time of the precharge timer. If the set time of the precharge timer is too short, the precharge of the capacitor 13 cannot be normally detected. On the other hand, if it is too long, it takes time to detect a state in which the precharge timer is not normally charged. For this reason, the set time of the precharge timer is set to a time during which the capacitor 13 that is not normally precharged can be detected quickly while the precharge of the fully discharged capacitor 13 is reliably detected within the set time. .

  The precharge time of the capacitor 13 is specified by the capacitance of the capacitor 13 and the electric resistance of the precharge resistor 6. Increasing the capacitance and increasing the electrical resistance of the precharge resistor 6 lengthen the precharge time of the capacitor 13. On the contrary, the precharge time can be shortened by reducing the capacitance of the capacitor 13 and the electric resistance of the precharge resistor 6. In the flowchart of FIG. 2, in other words, depending on the set voltage for comparing the voltage difference between the primary side and the secondary side of the contactor 2, it is determined whether the precharge is completed when the voltage difference decreases. Charge time varies. When the set voltage (20 V in the figure) for judging the precharge completion by comparing the voltage difference is lowered, the time for judging the precharge completion becomes longer. On the contrary, when the set voltage is increased, the time for judging the precharge completed is Shorter.

  Therefore, the set time of the precharge timer is set to an optimum value in consideration of the capacitance of the capacitor 13, the electric resistance of the precharge resistor 6 and the set voltage, for example, 400 to 1000 msec, preferably 450 to 800 msec, Preferably, it is set to 500 to 700 msec.

  As shown in the flowchart of FIG. 4, the power supply device that detects the completion of the precharge by the current for charging the capacitor 13, in other words, the current of the battery 1 for traveling or the precharge resistor 6, detects the current by the precharge timer. Thus, the time zone for detecting the completion of the precharge is specified. This power supply device turns off the switch of the precharge circuit 3 as a precharge error if the current of the running battery 1 detected by the current detection circuit 8 does not fall below the set current within the set time of the precharge timer. To precharge. If the current of the running battery 1 becomes smaller than the set current within the set time of the precharge timer, the contactor 2 is turned on, and then the precharge switch 7 is turned off, assuming that the precharge of the capacitor 13 is completed. Switch.

  As shown in the flowchart of FIG. 2, in the power supply device that detects the completion of the precharge based on the voltage difference between the primary side and the secondary side, when the voltage detection circuit 9 starts detecting the voltages on the primary side and the secondary side. The precharge timer starts counting. In the power supply device that detects the completion of the precharge by the current of the traveling battery 1 or the precharge resistor 6, the precharge timer starts counting when the current detection circuit 8 starts detecting the current.

  2 or 4, after the capacitor 13 is precharged, the contactor 2 is switched on so that power can be supplied from the traveling battery 1 to the load 11.

In the flowchart of FIG. 2, the power supply device switches the contactor 2 on in the following steps.
[Step of n = 1]
In this step, the control circuit 4 starts precharging the capacitor 13.
[Step of n = 2]
In this step, the control circuit 4 switches on the negative contactor 2. In this step, the positive contactor 2 is held off.
[Step n = 3]
The control circuit 4 switches the precharge switch 7 on. In this state, the traveling battery 1 is connected to the capacitor 13 via the precharge resistor 6. The precharge resistor 6 starts precharging of the capacitor 13 with the battery 1 for traveling while limiting the precharge current.
[Steps n = 4, 5]
When the precharge switch 7 is turned on and the precharge of the capacitor 13 is started, the start timer starts counting.
When a set time (50 msec in this figure) elapses after the start timer expires, the current detection circuit 8 detects a current for charging the capacitor 13 and compares the detected current with a set current (15A in the figure).
This power supply device determines that an excessive current does not flow through the load 11 when the current of the battery 1 for traveling or the precharge resistor 6 is smaller than 15 A at the timing when the start timer expires.
[Steps n = 6, 7]
If the detected current is larger than the set current, it is determined as a precharge error in which an excessive current flows through the load 11, and the precharge switch 7 is switched off to stop the precharge. When a precharge error occurs, the precharge is stopped, so the contactor 2 cannot be switched on.
[Step n = 8]
When the detection current of the current detection circuit 8 is smaller than the set current (15A), the intermediate timer starts counting. The set time (250 msec in this figure) elapses until the intermediate timer expires.
[Step n = 9]
The voltage detection circuit 9 detects the voltage difference between the primary side and the secondary side of the contactor 2. Further, the detection voltage difference detected by the voltage detection circuit 9 is compared with a set voltage (20V).
[Steps n = 10 and 11]
If the detected voltage difference is lower than the set voltage (20 V), it is determined that the precharge of the capacitor 13 is completed, the positive contactor 2 is switched on, and the precharge is terminated.
[Step n = 12]
When the detected voltage difference is higher than the set voltage, the precharge timer starts counting, and the steps of n = 9 and n = 12 are looped until the precharge timer expires, during which the detected voltage is set to the set voltage. If lower than that, it is determined that the precharge is completed, the plus-side contactor 2 is switched on, and the precharge is terminated.
[Steps n = 13 and 14]
Even if the precharge timer expires, if the detected voltage difference does not become lower than the set voltage and the precharge time becomes longer than the set time of the precharge timer, it is determined as a precharge error and the precharge switch 7 is turned off. To stop the precharge.

  Furthermore, as a modification of the above steps, it is also possible to replace n = 5 and n = 12, change the set value as appropriate, detect the voltage difference first, and then detect the current value It is.

In the flowchart of FIG. 4, the power supply device switches the contactor 2 on in the following steps.
[Step of n = 1]
In this step, the control circuit 4 starts precharging the capacitor 13.
[Step of n = 2]
In this step, the control circuit 4 switches on the negative contactor 2. In this step, the positive contactor 2 is held off.
[Step n = 3]
The control circuit 4 switches the precharge switch 7 on. In this state, the traveling battery 1 is connected to the capacitor 13 via the precharge resistor 6. The precharge resistor 6 starts precharging of the capacitor 13 with the battery 1 for traveling while limiting the precharge current.
[Steps n = 4, 5]
When the precharge switch 7 is turned on and the precharge of the capacitor 13 is started, the start timer starts counting.
When a set time (50 msec in this figure) elapses after the start timer expires, the current detection circuit 8 detects a current for charging the capacitor 13, and the detected first detection current is a first set current (15A in the figure). Compare to.
[Steps n = 6, 7]
If the first detection current is larger than the first set current, it is determined that a precharge error is caused by an excessive current flowing through the load 11, and the precharge switch 7 is switched off to stop the precharge. When a precharge error occurs, the precharge is stopped, so the contactor 2 cannot be switched on.
[Step n = 8]
When the first detection current detected by the current detection circuit 8 is smaller than the first set current (15A), the intermediate timer starts counting. The set time (250 msec in this figure) elapses until the intermediate timer expires.
[Step n = 9]
When the intermediate timer expires, the current detection circuit 8 detects the current of the traveling battery 1 and compares the second detection current detected by the current detection circuit 8 with the second set current (2A).
[Steps n = 10 and 11]
When the second detection current is lower than the second set current (2A), it is determined that the precharge of the capacitor 13 is completed, the positive contactor 2 is switched on, and the precharge is terminated.
[Step n = 12]
When the second detection current is higher than the second set current, the precharge timer starts counting, and the steps of n = 9 and n = 12 are looped until the precharge timer expires, during which the second When the detected current is lower than the second set current, it is determined that the precharge is completed, the plus-side contactor 2 is switched on, and the precharge is terminated.
[Steps n = 13 and 14]
Even if the precharge timer expires, if the second detection current does not become lower than the second set current and the precharge time becomes longer than the set time of the precharge timer, it is determined as a precharge error, and the precharge switch 7 is turned off to stop precharging.

It is a circuit diagram of the power supply device for vehicles concerning one example of the present invention. It is a flowchart which shows the switching method of the contactor concerning one Example of this invention. It is a graph which shows the characteristic of the pre-charge current of a capacitor. It is a flowchart which shows the switching method of the contactor concerning the other Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Battery for driving | running | working 2 ... Contactor 2A ... Contactor 2a on the plus side ... 1st contact
2B ... Negative contactor 2b ... Second contact 3 ... Precharge circuit 4 ... Control circuit 5 ... Secondary battery 6 ... Precharge resistor 7 ... Precharge switch 8 ... Current detection circuit 9 ... Voltage detection circuit 10 ... Output terminal 11 ... Load 12 ... Motor 13 ... Condenser

Claims (12)

A contactor (2) connected to the output side of the battery (1) for driving and controlling the power supply to the load (11) connected in parallel with the capacitor (13), and the contactor (2) A precharge circuit (3) having a precharge resistor (6) and a precharge switch (7) for limiting the precharge current of the capacitor (13) of the load (11) when switching on, and the precharge switch (7) and a control circuit (4) for controlling ON / OFF of the contactor (2), and after the precharge circuit (3) precharges the capacitor (13), the contactor (2) is switched on. A power supply device for a vehicle,
The control circuit (4) detects a start timer that starts counting after the precharge switch (7) is turned on, and a current that flows to the traveling battery (1) in a state in which the start timer expires. A current detection circuit (8) and a voltage detection circuit (9) for detecting a voltage difference between the primary side and the secondary side of the contactor (2);
The control circuit (4) compares the current of the running battery (1) detected by the current detection circuit (8) with the set current while the start timer expires, and then detects it by the voltage detection circuit (9). The voltage difference between the primary side and secondary side of the contactor (2) is compared with the set voltage, and the current of the battery for traveling (1) is smaller than the set current and the voltage difference is lower than the set voltage Thus, the power supply device for the vehicle that switches the contactor (2) on. A contactor (2) connected to the output side of the battery (1) for driving and controlling the power supply to the load (11) connected in parallel with the capacitor (13), and the contactor (2) A precharge circuit (3) having a precharge resistor (6) and a precharge switch (7) for limiting the precharge current of the capacitor (13) of the load (11) when switching on, and the precharge switch (7) and a control circuit (4) for controlling ON / OFF of the contactor (2), and after the precharge circuit (3) precharges the capacitor (13), the contactor (2) is switched on. A power supply device for a vehicle,
The control circuit (4) starts counting after the precharge switch (7) is turned on, and the primary and secondary sides of the contactor (2) with the start timer timed up. A voltage detection circuit (9) for detecting a voltage difference between the current and a current detection circuit (8) for detecting a current flowing in the traveling battery (1),
The control circuit (4) compares the voltage difference between the primary side and the secondary side of the contactor (2) detected by the voltage detection circuit (9) with the set voltage in the state where the start timer expires, and then The current of the running battery (1) detected by the current detection circuit (8) is compared with the set current, the voltage difference is lower than the set voltage, and the current of the running battery (1) is smaller than the set current Power supply device for the vehicle that switches the contactor (2) on. A contactor (2) connected to the output side of the battery (1) for driving and controlling the power supply to the load (11) connected in parallel with the capacitor (13), and the contactor (2) A precharge circuit (3) having a precharge resistor (6) and a precharge switch (7) for limiting the precharge current of the capacitor (13) of the load (11) when switching on, and the precharge switch (7) and a control circuit (4) for controlling ON / OFF of the contactor (2), and after the precharge circuit (3) precharges the capacitor (13), the contactor (2) is switched on. A power supply device for a vehicle,
The control circuit (4) detects a start timer that starts counting after the precharge switch (7) is turned on, and a current that flows to the traveling battery (1) in a state in which the start timer expires. A current detection circuit (8),
The control circuit (4) compares the first detection current detected by the current detection circuit (8) with the first set current in a state where the start timer expires, and then detects the first detection current detected by the current detection circuit (8). 2 contact currents are compared with a second set current smaller than the first set current, the first detected current is smaller than the first set current, and the second detected current is smaller than the second set current. (2) A vehicle power supply device that switches on.   The control circuit (4) has an intermediate timer, which detects the current of the battery (1) for traveling with the current detection circuit (8) and starts counting when the current is smaller than the set current. The power supply device for a vehicle according to claim 1, wherein the voltage detection circuit (9) detects a voltage difference and compares it with a set voltage in a state in which the intermediate timer expires.   The control circuit (4) is equipped with an intermediate timer, and this intermediate timer starts counting when the voltage detection circuit (9) detects the voltage difference and the voltage difference is lower than the set voltage. The power supply device for a vehicle according to claim 2, wherein the current detection circuit (8) detects the current of the traveling battery (1) and compares it with a set current in a time-up state.   The control circuit (4) includes an intermediate timer. This intermediate timer starts counting when the first detection current detected by the current detection circuit (8) is smaller than the first set current. The power supply device for a vehicle according to claim 3, wherein the current detection circuit (8) detects the second detection current and compares it with the second set current in a time-up state.   The control circuit (4) includes a precharge timer, and the precharge timer specifies a time during which the voltage detection circuit (9) detects a voltage difference, and the voltage detection circuit (9 2. The vehicle power supply device according to claim 1, wherein the precharge is interrupted by turning off the precharge switch (7) if the voltage difference detected at (1) does not drop to the set voltage.   The control circuit (4) is provided with a precharge timer, and this precharge timer specifies the time during which the current detection circuit (8) detects the current of the running battery (1), and the precharge timer setting time. If the current of the running battery (1) detected by the current detection circuit (8) does not decrease to the set current, the precharge switch (7) is turned off to interrupt the precharge. Power supply device for vehicles.   The control circuit (4) includes a precharge timer, and the precharge timer specifies a time during which the current detection circuit (8) detects the second detection current of the traveling battery (1). If the second detection current of the running battery (1) detected by the current detection circuit (8) does not drop to the second setting current during the set time, the precharge switch (7) is turned off and the precharge is interrupted. The vehicle power supply device according to claim 3. The contactor (2) connected to the output side of the battery for traveling (1) and controlling the power supply to the load (11) connected in parallel with the capacitor (13), and the contactor (2) from off to on When switching to the precharge circuit (3) having a precharge resistor (6) and a precharge switch (7) for limiting the precharge current of the capacitor (13) of the load (11), and the precharge switch (7 ) And a control circuit (4) for controlling ON / OFF of the contactor (2), and a method of switching the contactor (2) of the power supply device, which is connected in parallel to the load (11) with the precharge circuit (3) A method of switching a contactor of a power supply device for a vehicle that switches on a contactor (2) after precharging the capacitor (13)
When the precharge switch (7) is turned on, the start timer starts counting. When this start timer expires, the current flowing in the battery (1) is detected, and then the primary of the contactor (2) is detected. The voltage difference between the primary and secondary sides
After the start timer expires, the current of the battery (1) for running detected by the current detection circuit (8) is compared with the set current, and then the voltage difference detected by the voltage detection circuit (9) is set. Switching the contactor of the vehicle power supply device that turns on the contactor (2) when the current of the battery (1) for traveling is smaller than the set current and the voltage difference is lower than the set voltage compared to the voltage Method. The contactor (2) connected to the output side of the battery for traveling (1) and controlling the power supply to the load (11) connected in parallel with the capacitor (13), and the contactor (2) from off to on When switching to the precharge circuit (3) having a precharge resistor (6) and a precharge switch (7) for limiting the precharge current of the capacitor (13) of the load (11), and the precharge switch (7 ) And a control circuit (4) for controlling ON / OFF of the contactor (2), and a method of switching the contactor (2) of the power supply device, which is connected in parallel to the load (11) with the precharge circuit (3) A method of switching a contactor of a power supply device for a vehicle that switches on a contactor (2) after precharging the capacitor (13)
When the precharge switch (7) is turned on, the start timer starts counting. When the start timer expires, the voltage difference between the primary side and the secondary side of the contactor (2) is detected, and then Detects the current flowing in the battery for traveling (1)
After the start timer expires, the voltage difference detected by the voltage detection circuit (9) is compared with the set voltage, and then the current of the battery for traveling (1) detected by the current detection circuit (8) is further set. Switching the contactor of the vehicle power supply device that turns on the contactor (2) when the voltage difference is lower than the set voltage and the current of the battery (1) for travel is smaller than the set current compared to the current Method. The contactor (2) connected to the output side of the battery for traveling (1) and controlling the power supply to the load (11) connected in parallel with the capacitor (13), and the contactor (2) from off to on When switching to the precharge circuit (3) having a precharge resistor (6) and a precharge switch (7) for limiting the precharge current of the capacitor (13) of the load (11), and the precharge switch (7 ) And a control circuit (4) for controlling ON / OFF of the contactor (2), and a method of switching the contactor (2) of the power supply device, which is connected in parallel to the load (11) with the precharge circuit (3) A method of switching a contactor of a power supply device for a vehicle that switches on a contactor (2) after precharging the capacitor (13)
When the precharge switch (7) is turned on, it starts counting the start timer, and when this start timer expires, it detects the current flowing to the battery for traveling (1),
After the start timer expires, the first detection current detected by the current detection circuit (8) is compared with the first set current, and then the second detection current detected by the current detection circuit (8) is further calculated. In the state where the first detection current is smaller than the first setting current and the second detection current is smaller than the second setting current, the contactor (2) is compared with the second setting current smaller than the first setting current. A method for switching a contactor of a vehicle power supply device to be turned on.

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