JP2012115006A - Charging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charging device capable of preventing an unnecessary voltage from being applied to the other charger when only one charger is charged by a single-phase power supply without complexing the structure, increasing the device size, or reducing the reliability.SOLUTION: A charging device has: a master charger having a CPU, a power supply circuit, and a charging circuit; and a plurality of slave chargers each having a CPU, a power supply circuit, and a charging circuit. The charging device is configured so that both the master charger and the slave chargers are operated when a three-phase power supply is powered on, and that only the master charger is operated when a single-phase power supply is powered on. In the charging device, a start-up voltage condition for the slave chargers is set to be higher than that for the master charger.

Description

The present invention relates to a charging device mounted on, for example, a hybrid vehicle or an electric vehicle, and in particular, when a three-phase power is turned on, both a master charger and a slave charger are operated simultaneously, and when a single-phase power is turned on, the master charger It is related with what was devised so that it may prevent that a slave charger operate | moves unnecessarily at the time of single phase power activation.

  A conventional charging device and power supply equipment mounted on a hybrid vehicle or an electric vehicle have a configuration as shown in FIG. 5, for example. First, there is a power supply facility 101, and the power supply facility 101 includes a three-phase power supply 103 and a single-phase power supply 105. The three-phase power source 103 is connected to a three-phase power source charging plug 107 via an R-phase power source line 109, an S-phase power source line 111, a T-phase power source line 113, and a ground line 115.

  The single-phase power supply 105 is connected to a single-phase power supply charging plug 117 via an L-phase power supply line 119, an N-phase power supply line 121, and a ground line 123.

  On the other hand, although it is the structure by the side of the charging device mounted in the hybrid vehicle or the electric vehicle, three chargers, ie, the master charger 125 and the slave chargers 127 and 129 are installed. The master charger 125 is provided with a CPU 131, a power supply circuit 133, and a charging circuit 135. Similarly, the slave chargers 127 and 129 are also provided with a CPU 131, a power supply circuit 133, and a charging circuit 135.

  A three-phase power inlet 137 and a single-phase power inlet 139 are installed on the master charger 125 and slave chargers 127 and 129 side. The three-phase power inlet 137 and the master charger 125 are connected to each other via an L1-phase power line 141, an L2-phase power line 143, and a ground line 145. The three-phase power inlet 137 and the slave charger 127 are connected via an L2-phase power line 143, an L3-phase power line 147, and a ground line 145. The three-phase power inlet 137 and the slave charger 129 are connected via an L1-phase power line 141, an L3-phase power line 147, and a ground line 145.

The L1-phase power line 148, L2-phase power line 149, and ground line 151 fed from the single-phase power inlet 139 are branched and connected to the L1-phase power line 141, L2-phase 143, and ground line 145, respectively. Has been.
In the figure, reference numeral 153 denotes a battery.

  In the above configuration, when the three-phase power source 103 is turned on, that is, when the three-phase power source inlet 137 is inserted into the three-phase power source charging plug 107, three chargers, that is, the master charger 125 and the slave charger 127 and 129 are operated, and when the single-phase power supply 105 is turned on, only one charger, that is, the master charger 125 is operated.

  In the above configuration, as shown in FIG. 6, when the single-phase power supply 105 is turned on, that is, when the single-phase power supply inlet 139 is inserted into the three-phase power supply charging plug 117, only the master charger 125 is charged. If it does so, a voltage will be applied to the two slave chargers 127 and 129 between the points a to d. That is, depending on the circuit impedance of the power supply circuits 133 and 133 of the slave chargers 127 and 129, the circuit impedance of the power supply circuit 133 of the point a to the slave charger 127 to point c to the circuit of the power supply circuit 133 of the slave charger 129. A voltage is applied through the path from impedance to point d. For example, when 200 V is applied, about half of the voltage of 100 V is applied to each of the slave chargers 127 and 129.

  Since the slave chargers 127 and 129 are designed to operate with an input of 100 V, the slave chargers 127 and 129 do not need to operate originally but operate unnecessarily. . Further, when the slave chargers 127 and 129 operate unnecessarily, the circuit impedance of the power supply circuits 133 and 133 of the slave chargers 127 and 129 changes depending on the operation state. When the circuit impedance changes, the input voltage to which a voltage of about 100 V has been applied fluctuates due to the impedance change, which causes an unstable operation state, and the slave charger 127, There was a risk that 129 would be damaged.

  Conventionally, in order to solve this type of problem, as shown in FIG. 7, it has been considered to insert and arrange a relay 151 driven by AC 200 V in the power supply route of the slave chargers 127 and 129. In this case, the contact of the relay 151 is switched depending on whether the three-phase power source 103 is turned on or the single-phase power source 105 is turned on, so that when the single-phase power source 105 is turned on, the slave chargers 127 and 129 are switched. Is not working inadvertently.

  In addition, a configuration as shown in FIG. 8 is also considered. In this case, a slave power supply 161 for the single-phase power supply 105 is separately installed, and when the single-phase power supply 105 is turned on, the slave charger 161 for the single-phase power supply is operated. .

  For example, Patent Document 1 discloses a configuration of this type of power supply device.

Japanese Patent Application Laid-Open No. 07-046713

The conventional configuration has the following problems.
First, in the case of the configuration shown in FIG. 7 using the relay 161, there is a problem that the relay that can be mounted on the vehicle and driven by an alternating current has few types and is expensive. There was also a problem in terms of reliability. Specifically, there are problems such as deterioration due to vibration, poor energization due to contact failure, abnormal heat generation, and malfunction due to coil deterioration. Further, as shown in FIG. 7, it is necessary to increase the number of power supply lines 153, which may increase the weight and cost.
Further, in the case of the configuration shown in FIG. 8 in which the slave charger 161 dedicated to the single-phase power source 105 is provided, naturally, the configuration is complicated, the size of the device is increased, and the cost is increased. There was a problem.

  The present invention has been made based on such points, and the object of the present invention is to provide a single charger with a single-phase power source without complicating the configuration, increasing the size of the apparatus, and reducing reliability. It is an object of the present invention to provide a charging device that does not operate when the other charger does not need to be activated when actually charging.

In order to achieve the above object, a charging device according to claim 1 of the present invention includes a master charger including a CPU, a power supply circuit and a charging circuit, a plurality of slave chargers including a CPU, a power supply circuit and a charging circuit, The charging is configured to operate both the master charger and the slave charger when the three-phase power source is turned on, and to operate only the master charger when the single-phase power source is turned on. In the apparatus, the starting voltage condition of the slave charger is set higher than the starting voltage condition of the master charger.
According to a second aspect of the present invention, there is provided a charging device comprising a master charger having a CPU, a power supply circuit and a charging circuit, and a plurality of slave chargers having a CPU, a power supply circuit and a charging circuit, and a three-phase power supply. In the charging apparatus configured to operate both the master charger and the slave charger when the power is turned on, and to operate only the master charger when the single-phase power is turned on, the master charger It is determined whether the power source input to the three-phase power source or the single-phase power source, and the slave charger is operated only when it is determined that the input is from the three-phase power source. Is.

As described above, according to the charging device according to claim 1 of the present invention, a master charger including a CPU, a power supply circuit, and a charging circuit, a plurality of slave chargers including a CPU, a power supply circuit, and a charging circuit, The charging is configured to operate both the master charger and the slave charger when the three-phase power source is turned on, and to operate only the master charger when the single-phase power source is turned on. The device has a configuration in which the start-up voltage condition of the slave charger is set higher than the start-up voltage condition of the master charger, thereby reliably preventing unnecessary operation of the slave charger when the single-phase power is turned on. can do.
The charging device according to claim 2 includes a master charger including a CPU, a power supply circuit, and a charging circuit, and a plurality of slave chargers including a CPU, a power supply circuit, and a charging circuit. In the charging device configured to operate both the master charger and the slave charger when the power is turned on and to operate only the master charger when the single-phase power is turned on, the master charging is performed. It is configured to determine whether the power input to the charger is a three-phase power source or a single-phase power source, and to operate the slave charger only when it is determined that the input is from a three-phase power source. Therefore, it is possible to reliably prevent unnecessary operation of the slave charger when the single-phase power supply is turned on.

It is a figure which shows the 1st Embodiment of this invention, and is a block diagram which shows the structure of a charging device and power supply equipment. It is a figure which shows the 1st Embodiment of this invention, and is a circuit diagram which shows the structure of the power supply circuit of a charging device. It is a figure which shows the 2nd Embodiment of this invention, and is a block diagram which shows the structure of a charging device and power supply equipment. It is a figure which shows the 2nd Embodiment of this invention, and is a circuit diagram which shows the structure of a power supply circuit. It is a figure which shows a prior art example, and is a block diagram which shows the structure of a charging device and power supply equipment. It is a figure which shows a prior art example, and is a block diagram which shows the structure of a charging device and power supply equipment. It is a figure which shows a prior art example, and is a block diagram which shows the structure of a charging device and power supply equipment. It is a figure which shows a prior art example, and is a block diagram which shows the structure of a charging device and power supply equipment.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. The charging device and the power supply facility according to the present embodiment are configured as shown in FIG. First, there is a power supply facility 1, which is composed of a three-phase power supply 3 and a single-phase power supply 5. The three-phase power source 3 is connected to a three-phase power source charging plug 7 via an R-phase power source line 9, an S-phase power source line 11, a T-phase power source line 13, and a ground line 15.

  The single-phase power source 5 is connected to a single-phase power source charging plug 17 via an L-phase power source line 19, an N-phase power source line 21, and a ground line 23.

  On the other hand, although it is the structure by the side of the charging device mounted in a hybrid vehicle or an electric vehicle, three chargers, ie, the master charger 25 and the slave chargers 27 and 29, are installed. The master charger 25 is provided with a CPU 31, a power supply circuit 33, and a charging circuit 35. Similarly, the slave chargers 27 and 29 are provided with a CPU 31, a power supply circuit 33, and a charging circuit 35, respectively.

  On the master charger 25 and slave chargers 27 and 29 side, a three-phase power inlet 37 and a single-phase power inlet 39 are installed. The three-phase power supply inlet 37 and the master charger 25 are connected via an L1-phase power line 41, an L2-phase power line 43, and a ground line 45. The three-phase power inlet 37 and the slave charger 27 are connected via an L2-phase power line 43, an L3-phase power line 47, and a ground line 45. The three-phase power inlet 37 and the slave charger 29 are connected via an L1-phase power line 41, an L3-phase power line 47, and a ground line 45.

The L1-phase power line 47, L2-phase power line 49, and ground line 51 fed out from the single-phase power inlet 39 branch to the L1-phase power line 41, L2-phase power line 43, and ground line 45, respectively. ·It is connected.
In the figure, reference numeral 53 denotes a battery.

  In the above configuration, when the three-phase power source 3 is turned on, that is, when the three-phase power source inlet 37 is inserted into the three-phase power source charging plug 7, three chargers, that is, the master charger 25 and the slave charger When the single-phase power supply 5 is turned on, that is, when the single-phase power supply inlet 39 is inserted into the three-phase power supply charging plug 17, the single charger, that is, the master charge is operated. Only the device 25 is operated.

Each power supply circuit 33 of the master charger 25 and the slave chargers 27 and 29 is provided with an activation voltage setting terminal 61. Hereinafter, the configuration of the power supply circuit 33 including the starting voltage setting terminal 61 will be described with reference to FIG. First, there are AC power supply input terminals 63 and 65. In the case of the master charger 25, for example, the AC power supply terminals 63 and 65 are connected via the L1 phase power supply line 41 and the L2 phase power supply line 43. The power is turned on.

  A diode bridge 67 is installed between the AC power supply terminals 63 and 65, a smoothing capacitor 69, a limiting resistor 71, a plurality (six in this embodiment) of Zener diodes 73, and a power supply IC 75. A switching element 77, a transformer 79, a rectifier diode 81, a smoothing capacitor 83, and a capacitor 85 are provided.

  In the above configuration, when AC power is turned on between the AC power terminals 63 and 65, rectification is performed by the diode bridge 67, ripple voltage is absorbed by the smoothing capacitor 69, and DC voltage is generated. The DC voltage is supplied to the power supply IC 75 via the limiting resistor 71 and a plurality of (six in the case of this embodiment) Zener diodes 73. Then, the power supply IC 75 is activated by a preset voltage / current, and outputs a PWM waveform to the switching element 77. Thereby, the switching element 77 is driven.

  At this time, due to the influence of the forward voltage of the Zener diode 73, the voltage supplied to the power supply IC 75 is lower when the starting voltage setting terminal 61 is open than when the start voltage setting terminal 61 is closed, and the current is also increased. Less. That is, when the starting voltage setting terminal 61 is closed, the four Zener diodes 73 are bypassed. On the other hand, when the starting voltage setting terminal 61 is open, a total of six All of the Zener diodes 73 of this will function. As a result, when the starting voltage setting terminal 61 is open, the voltage supplied to the power supply IC 75 is lower and the current is smaller when the start voltage setting terminal 61 is open.

Therefore, when the starting voltage setting terminal 61 is open, a higher voltage is required to supply the same voltage to the power supply IC 75. That is, if the voltage applied to the AC power supply terminals 63 and 65 is not higher when the start voltage setting terminal 61 is open than when the start voltage setting terminal 61 is closed, the power IC 75 will not start. In the case of the present embodiment, this is used to prevent unnecessary operation of the slave chargers 27 and 29 when the single-phase power supply 5 is turned on.

The operation will be described based on the above configuration.
First, the start-up voltage setting terminal 61 of each power supply circuit 33 of the master charger 25 and the slave chargers 27 and 29 is shown in FIG. 1, but the start-up voltage setting of the power supply circuit 33 of the master charger 25 is shown in FIG. The terminal 61 is in a closed state, while the starting voltage setting terminal 61 of each power supply circuit 33 of the slave chargers 27 and 29 is in an open state.

  When the three-phase power supply 3 is turned on in the above state, a voltage of 200 V is equally applied to the power supply circuit 33 of the master charger 25 and the slave chargers 27 and 29, whereby the master charger 25 All of the slave chargers 27 and 29 operate. Since the start voltage setting terminal 61 of each power supply circuit 33 of the slave chargers 27 and 29 is in an open state, it does not start unless a high voltage (for example, 170 V or more) is applied. In this case, since a voltage of 200 V is equally applied, the slave chargers 27 and 29 operate simultaneously.

On the other hand, when the single-phase power source 5 is turned on, the master charger 25 operates, but the slave chargers 27 and 29 do not operate.
For example, when the single-phase power supply 5 is turned on at a single-phase 100V, 100V is applied to the master charger 25, and 50V is applied to the slave chargers 27 and 29, respectively. become. At that time, since the start-up voltage setting terminal 61 of the power supply circuit 33 of the master charger 25 is closed, it can be started even at a low voltage (for example, AC 80 V or more). 25 will be activated.

  On the other hand, since the start-up voltage setting terminal 61 of the power supply circuit 33 of the slave chargers 27 and 29 is open, it cannot be started unless it is a high voltage (for example, AC 170 V or more). It does not start with 50V.

Next, for example, when the single-phase power supply 5 is turned on at a single-phase 200V, 200V is applied to the master charger 25, and 100V is applied to the slave chargers 27 and 29, respectively. Will be. The master charger 25 is activated by the 200V.

  On the other hand, since the start-up voltage setting terminal 61 of the power supply circuit 33 of the slave chargers 27 and 29 is open, it cannot be started unless it is a high voltage (for example, AC 170 V or more). It is not activated by 100V.

As described above, according to the present embodiment, the following effects can be obtained.
First, it is possible to prevent the slave chargers 27 and 29 from operating unnecessarily when the single-phase power supply 5 is turned on. This is configured so that the start-up voltage setting terminal 61 of the power supply circuit 33 of the slave chargers 27 and 29 is open and does not start unless a high voltage (for example, 170 V or more) is applied. Since such a high voltage (for example, 170 V or more) is not applied when 5 is turned on, the slave chargers 27 and 29 do not operate unnecessarily.
In addition, as a configuration for preventing the slave chargers 27 and 29 from needlessly operating, it is only necessary to newly provide a starting voltage setting terminal 61, so that a desired effect can be obtained with a simple configuration. It is.

Next, a second embodiment of the present invention will be described with reference to FIGS. In this case, a part of the configuration of the power supply circuit 33 is different from the case of the first embodiment. That is, as shown in FIG. 3, a voltage detection circuit 91 is installed on the master charger 25 side and a power activation signal line 93 is installed. Further, as shown in FIG. 4, in the power supply circuit 33 of the slave chargers 27 and 29, a plurality of (six in the case of the first embodiment) Zeners in the case of the first embodiment. Instead of the diode 73, a photocoupler 95 is installed, and power activation signal lines 97 and 99 connected to the power activation signal line 93 are installed.
Other configurations are the same as those of the first embodiment, and therefore, the same reference numerals are given to the same portions in the drawings, and the description thereof is omitted.

  The operation will be described based on the above configuration. First, the start-up voltage setting terminal 61 of each power supply circuit 33 of the master charger 25 and the slave chargers 27 and 29 is set to the start-up voltage setting of the power supply circuit 33 of the master charger 25 as shown in FIG. The terminal 61 is in a closed state, while the starting voltage setting terminal 61 of each power supply circuit 33 of the slave chargers 27 and 29 is in an open state.

  In the above state, when the three-phase power supply 3 is turned on, a voltage of 200 V is applied to the master charger 25, whereby the master charger 25 operates. On the other hand, in each power supply circuit 33 of the slave chargers 27 and 29, the start-up voltage setting terminal 61 is in an open state, so that the power supply IC 75 does not start.

  In this case, the CPU 31 of the power supply circuit 33 of the master charger 25 determines whether or not the voltage detected by the voltage detection circuit 91 is a predetermined voltage (for example, 180V). In this case, since a voltage of 200 V is applied, it is determined that the voltage is higher than a predetermined voltage (for example, 180 V), and a power activation signal is output via the power activation signal line 93. The LED of the photocoupler 95 shown in FIG. 4 is turned “ON” by this power supply activation signal, whereby a voltage is supplied to the power supply IC 75 of each power supply circuit 33 of the slave chargers 27 and 29. As a result, the slave chargers 27 and 29 also operate.

On the other hand, when the single-phase power source 5 is turned on, the master charger 25 operates, but the slave chargers 27 and 29 do not operate.
For example, when the single-phase power supply 5 is turned on at a single-phase 100V, 100V is applied to the master charger 25, and 50V is applied to the slave chargers 27 and 29, respectively. become. At that time, since the start-up voltage setting terminal 61 of the power supply circuit 33 of the master charger 25 is closed, it can be started even at a low voltage (for example, AC 80 V or more). Become.

  On the other hand, since the starting voltage setting terminal 61 of the power supply circuit 33 of the slave chargers 27 and 29 is open, no voltage is supplied to the power supply IC 75 of the power supply circuit 33 as it is. Never do. Further, the detection circuit 91 of the master charger 25 detects a voltage of 50V, which is lower than a predetermined voltage (for example, 180V) set in advance, so that the single-phase power supply 5 is turned on. Therefore, the power activation signal is not output via the power-on signal line 93. Eventually, the slave chargers 27 and 29 do not operate.

Further, for example, when the single-phase power supply 5 is turned on at a single-phase 200V, 200V is applied to the master charger 25, and 100V is applied to the slave chargers 27 and 29, respectively. Will be. The master charger 25 is activated by the 200V.

  On the other hand, since the starting voltage setting terminal 61 of the power supply circuit 33 of the slave chargers 27 and 29 is open, no voltage is supplied to the power supply IC 75 of the power supply circuit 33 as it is. Never do. In addition, the detection circuit 91 of the master charger 25 detects a voltage of 100V, which is lower than a predetermined voltage (for example, 180V), so that the single-phase power supply 5 is turned on. Therefore, the power activation signal is not output via the power activation signal line 93. Eventually, in this case as well, the slave chargers 27 and 29 do not operate.

  Therefore, it is possible to prevent the slave chargers 27 and 29 from operating unnecessarily when the single-phase power supply 5 is turned on, and the same effects as in the case of the first embodiment. Can be played.

The present invention is not limited to the first and second embodiments.
In the first and second embodiments, the case where two slave chargers are installed has been described as an example, but three or more may be used.
The illustrated configuration is merely an example.

  The present invention relates to a charging device mounted on, for example, a hybrid vehicle or an electric vehicle, and in particular, when a three-phase power is turned on, both a master charger and a slave charger are operated simultaneously, and when a single-phase power is turned on, the master charger For example, it is suitable for a charging device for charging various electric vehicles, for example, in which the slave charger is prevented from operating unnecessarily when the single-phase power is turned on.

1 Power supply equipment 3 Three-phase power supply 5 Single-phase power supply 25 Master charger 27 Slave charger 29 Slave charger 31 CPU
33 power supply circuit 35 charging circuit 61 start-up voltage setting terminal 91 detection circuit

Claims (2)

A master charger provided with a CPU, a power supply circuit and a charging circuit, and a plurality of slave chargers provided with a CPU, a power supply circuit and a charging circuit, and when the three-phase power supply is turned on, the master charger In a charging device configured to operate only the master charger when operating both the slave charger and the single-phase power supply,
2. A charging device, wherein a starting voltage condition of the slave charger is set higher than a starting voltage condition of the master charger. A master charger provided with a CPU, a power supply circuit and a charging circuit, and a plurality of slave chargers provided with a CPU, a power supply circuit and a charging circuit, and when the three-phase power supply is turned on, the master charger In a charging device configured to operate only the master charger when operating both the slave charger and the single-phase power supply,
Whether the power input to the master charger is a three-phase power source or a single-phase power source, and the slave charger is operated only when it is determined that the input is from a three-phase power source A charging device.

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