JP2012105408A - Power supply apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact power supply apparatus.SOLUTION: When voltage detection means 311 detects a voltage Vs1 of a first battery 1 to find that the voltage Vs1 is less than a first value V1, a control circuit 310 closes a first switching element 112 to apply the sum of voltages of the first battery 1 and a second battery 111 to a DC/DC converter 210, which in turn boosts it for supply to a load 4. When the voltage Vs1 is not less than the first value V1 and is less than a second value V2, the first switching element 112 is opened and the DC/DC converter 210 is operated. When the voltage Vs1 is not less than the second value V2, the first switching element 112 is opened and the DC/DC converter 210 is stopped to apply the voltage of the first battery 1 to the load 4 as it is. The voltage Vs2 of the second battery 111 can compensate a temporary voltage drop to facilitate a reduced capacity of the DC/DC converter 210 and miniaturize the power supply apparatus.

Description

  The present invention relates to an improvement of a power supply device, for example, a power supply device mounted on a vehicle.

  In a power supply device having a battery and the voltage of the battery being lowered only at a certain timing, for example, a power supply device such as an idling stop system for stopping the engine when the vehicle is stopped, a device that is operated by the battery when the battery voltage is lowered. Therefore, a DC / DC converter that boosts the lowered battery voltage is required (see, for example, Patent Document 1).

JP 2003-237501 A (paragraph numbers 0017 to 0023 and FIG. 1)

  The conventional power supply is configured as described above, and when used in a system in which the battery voltage drops suddenly for a short time and then recovers to some extent, such as an idling stop system of an automobile, Therefore, a DC / DC converter must be designed for a period in which the battery voltage drop is greatest, and a large DC / DC converter must be used.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain a power supply device that can be miniaturized.

In the power supply device according to the present invention,
A power supply device having a first DC voltage source, a series voltage source device, a DC-DC converter, and a control device,
The series voltage source device has a second DC voltage source and switching means,
The DC-DC converter has an input terminal, an output terminal, and a booster circuit. The booster circuit boosts a DC voltage input to the input terminal and outputs the boosted voltage from the output terminal. Is designed to conduct between the input terminal and the output terminal,
The input terminal of the DC-DC converter is connected to the first DC voltage source via the series voltage source device, and a load is connected to the output terminal,
The control device controls the switching means so that the first DC voltage source and the second DC voltage source are connected in series, and the voltage of the first DC voltage source and the second DC voltage source are The booster circuit switches between a first state in which a voltage added to the input terminal is applied to the input terminal and a second state in which the voltage of the first DC voltage source is independently applied to the input terminal. It controls the operation.

This invention
A power supply device having a first DC voltage source, a series voltage source device, a DC-DC converter, and a control device,
The series voltage source device has a second DC voltage source and switching means,
The DC-DC converter has an input terminal, an output terminal, and a booster circuit. The booster circuit boosts a DC voltage input to the input terminal and outputs the boosted voltage from the output terminal. Is designed to conduct between the input terminal and the output terminal,
The input terminal of the DC-DC converter is connected to the first DC voltage source via the series voltage source device, and a load is connected to the output terminal,
The control device controls the switching means so that the first DC voltage source and the second DC voltage source are connected in series, and the voltage of the first DC voltage source and the second DC voltage source are The booster circuit switches between a first state in which a voltage added to the input terminal is applied to the input terminal and a second state in which the voltage of the first DC voltage source is independently applied to the input terminal. Therefore, it is possible to reduce the size.

It is a block diagram which shows the structure of the power supply device which is Embodiment 1 of this invention. It is explanatory drawing for demonstrating operation | movement of the power supply device of FIG. FIG. 6 is a configuration diagram illustrating a configuration of a power supply device according to a second embodiment. FIG. 6 is a configuration diagram illustrating a configuration of a power supply device according to a third embodiment. FIG. 10 is a configuration diagram illustrating a configuration of a power supply device according to a fourth embodiment. FIG. 10 is a configuration diagram illustrating a configuration of a power supply device according to a fifth embodiment. FIG. 10 is a configuration diagram illustrating a configuration of a power supply device according to a sixth embodiment. FIG. 10 is a configuration diagram illustrating a configuration of a power supply device according to a seventh embodiment. FIG. 20 is a configuration diagram illustrating a configuration of a power supply device according to an eighth embodiment. FIG. 20 is a configuration diagram illustrating a configuration of a power supply device according to a ninth embodiment. FIG. 20 is a configuration diagram showing a configuration of a power supply device according to Embodiment 10. FIG. 38 is a configuration diagram showing a configuration of a power supply device according to an eleventh embodiment.

Embodiment 1 FIG.
1 and 2 show a first embodiment for carrying out the present invention. FIG. 1 is a configuration diagram showing a configuration of a power supply device, and FIG. 2 is an explanatory diagram for explaining an operation. In FIG. 1, the power supply device 11 includes a series voltage source circuit 110, a DC / DC converter 210 as a DC-DC converter, and a control circuit 310. The series voltage source circuit 110 includes a second DC voltage source, a power storage unit, a second battery 111 as a secondary battery, a first switching element 112 as an opening / closing unit, and a first diode 113 as a one-way conduction unit. . The first switching element 112 and the first diode 113 are switching means in the present invention. In this embodiment, a MOSFET (Metal Oxide Semiconductor Field Effect Transistor) having a parasitic diode connected in parallel is used as the first switching element 112. The source of the first switching element 112 is connected to the negative side of the second battery 111, and the second battery 111 and the first switching element 112 are connected in series. The cathode of the first diode 113 is connected to the positive side of the second battery 111, the anode of the first diode 113 is connected to the drain side of the first switching element 112, and the second battery 111 and the first switching element 112 are connected in series. A first diode 113 is connected in parallel to the circuit.

  The DC / DC converter 210 is a general step-up DC / DC converter, and includes a first inductor 211, a second switching element 212, a second diode 213, a smoothing capacitor 214, positive and negative input terminals 215a and 215b, It has positive and negative output terminals 216a, 216b. As the second switching element 212, a MOSFET having a parasitic diode connected in parallel is used. The first inductor 211 and the second switching element 212 are connected in series so that the drain of the second switching element 212 is on the first inductor 211 side, and the other side of the first inductor 211 is connected to the positive input terminal 215a. The drain side of the second switching element 212 is connected to the negative input terminal 215b. The first inductor 211 as the boosting inductor, the second switching element 212 as the boosting switching means, and the second diode 213 as the boosting unidirectional conduction means are the boosting circuit in the present invention.

  The anode side of the second diode 213 is connected to the series connection point of the first inductor 211 and the second switching element 212, and the cathode side of the second diode 213 is connected to the output terminal 216a. Also, the negative input terminal 215b and the negative output terminal 216b are directly connected. The smoothing capacitor 214 is connected between the output terminals 216a and 216b. Then, the second switching element 212 is opened and closed at a high frequency, the input voltage Va input to the input terminals 215a and 215b is boosted, and output from the output terminals 216a and 216b. The step-up ratio is determined by the duty ratio of switching the opening / closing of the second switching element 212 (the ratio of the closing time to the opening / closing cycle). When the DC / DC converter 210 is not operated, the second switching element 212 is opened.

  A connection point between the first switching element 112 and the first diode 113 of the series voltage source circuit 110 is connected to the positive side of the first battery 1 as the first DC voltage source. The positive input terminal 215 a of the DC / DC converter 210 is connected to the positive side of the second battery 111 of the series voltage source circuit 110, and the negative input terminal 215 b is connected to the negative side of the first battery 1. The load 4 is connected to the output terminals 216a and 216b of the DC / DC converter 210. The control circuit 310 includes voltage detection means 311. The control circuit 310 detects the terminal voltage of the first battery 1 with the voltage detection means 311, issues a control signal to each gate of the first switching element 112 and the second switching element 212, and controls opening and closing of each. The power supply device 11 is configured as described above.

  Next, the operation will be described with reference to FIG. The control circuit 310 detects the voltage Vs1 of the first battery 1 by the voltage detection unit 311 and performs an operation of closing the first switching element 112 of the series voltage source circuit 110 depending on whether the voltage is higher or lower than the threshold value. The desired voltage can be supplied to the load 4 depending on whether the DC / DC converter 210 is operated, both are operated, or both are not operated. That is, when the voltage Vs1 of the first battery 1 is less than a first value V1 (for example, 6V), the first switching element 112 of the series voltage source circuit 110 is closed and the DC / DC converter 210 is operated. When the voltage Vs1 is not less than the first value V1 (V1 <V2) and less than the second value V2 (for example, 10 V), only the DC / DC converter 210 is operated. When the voltage Vs1 is equal to or higher than the second value V2, neither the operation of closing the first switching element 112 of the series voltage source circuit 110 nor the operation of the DC / DC converter 210 is performed.

Specifically, the operation when the voltage Vs1 of the first battery 1 changes as shown in FIG. 2 is as follows.
During the period from start to time t1 when the voltage Vs1 of the first battery 1 is equal to or greater than the second value V2, the first switching element 112 is opened so that the voltage of the first battery 1 is increased. The voltage of the second battery 111 is not added, and the DC / DC converter 210 does not perform the step-up operation, and the voltage Vs1 of the first battery 1 is applied alone to the load. A state where the voltage Vs1 of the first battery 1 is applied to the load alone is the second state (the first state will be described later) in the present invention. In this case, current flows through the following path.
First battery 1 → first diode 113 → DC / DC converter 210 (simply passes only) → load 4 → DC / DC converter 210 → first battery 1

At time t1, when a large load is applied and the voltage Vs1 drops below the first value V1 (V1 <V2), the control circuit 310 closes the first switching element 112, and thus the voltage Vs1 of the first battery 1 and the first voltage Vs1. 2 The voltage Vst obtained by adding the voltage Vs2 of the battery 111 is applied to the DC / DC converter 210, and the DC / DC converter 210 is operated and boosted. In this case, current flows through the following path.
First battery 1 → first switching element 112 → second battery 111 → DC / DC converter 210 (step-up operation) → load 4 → DC / DC converter 210 → first battery 1
By controlling in this way, a decrease in the voltage Vs1 of the first battery 1 can be compensated by the voltage Vs2 of the second battery 111.

When the load becomes light and the voltage Vs1 recovers to the first value V1 or more at the time t2 and is less than the second value V2 (V1 <= Vs1 <V2), the first switching element 112 is opened to open the first switching element 112. The voltage of the second battery 111 is not added to the voltage of the battery 1, the voltage Vs 1 of the first battery 1 is applied alone to the DC / DC converter 210, and the applied voltage is DC / DC converter 210 boosts the voltage. In this case, current flows through the following path.
First battery 1 → first diode 113 → DC / DC converter 210 (step-up operation) → load 4 → DC / DC converter 210 → first battery 1
By controlling in this way, the voltage of the first battery 1 is independent and the first diode without opening / closing the first switching element 112 of the series voltage source circuit 110, that is, with the first switching element 112 opened. The voltage is applied to the DC / DC converter 210 via 113.

Further, at time t3, when the voltage Vs1 becomes equal to or higher than the second value V2, the first switching element 112 is opened so that the voltage of the second battery 111 is not added to the voltage of the first battery 1. In addition, the step-up operation of the DC / DC converter 210 is stopped and the voltage Vs1 of the first battery 1 is applied to the load. In this case, current flows through the following path.
First battery 1 → first diode 113 → DC / DC converter 210 (simply passes only) → load 4 → DC / DC converter 210 → first battery 1

  It should be noted that the combination of operations of the series voltage source circuit 110 and the DC / DC converter 210 shown here is an example, and it is possible to operate in a different combination depending on conditions. Further, although the battery 111 is used as the second DC voltage source, another DC voltage source such as a capacitor may be used as long as it is a DC voltage source.

  As described above, according to this embodiment, the series voltage source circuit 110 is provided between the first battery 1 and the DC / DC converter 210, and the voltage Vs 2 of the second battery 111 is added to the voltage Vs 1 of the first battery 1. Can be supplied to the DC / DC converter 210, whereby the DC / DC converter 210 can be reduced in size, and the power supply apparatus as a whole can also be reduced in size.

Embodiment 2. FIG.
FIG. 3 is a configuration diagram illustrating a configuration of the power supply device according to the second embodiment. In FIG. 3, the power supply device 12 includes a control circuit 320 having program means 321. The control circuit 320 is. Since other configurations are the same as those of the first embodiment shown in FIG. 1, the same reference numerals are given to the corresponding components and the description thereof is omitted. In the power supply device 11 shown in the first embodiment, if the voltage change pattern of the first battery 1 is known, the program unit 321 sets the first switching element of the series voltage source circuit 110 in accordance with the elapsed time. The series voltage source circuit 110 and the DC / DC converter 210 are controlled by issuing a signal so as to select whether the circuit is closed, the DC / DC converter 210 is operated, both are operated, or both are not operated. To do.

The program means 321 controls as follows. In FIG. 2, the voltage of the first battery 1 is set by opening the first switching element 112 from the time point 0 at which the program unit 321 starts operating as a predetermined time until before the time t1 as the first time. The voltage of the second battery 111 is not added, the second state is set, and the DC / DC converter 210 is not boosted so that the voltage Vs1 of the first battery 1 is applied to the load.
The control circuit 310 closes the first switching element 112 until the time t2 as the second time before reaching the time t2, and the voltage Vs1 of the first battery 1 and the voltage Vs2 of the second battery 111 are added. The added voltage Vst is applied to the DC / DC converter 210 in a first state, and the voltage Vst is boosted by operating the DC / DC converter 210.

Until the time t3 as the third time is reached before the time t2, the first switching element 112 is opened so that the voltage of the second battery 111 is not added to the voltage of the first battery 1. The voltage Vs1 is applied to the DC / DC converter 210 alone, and the applied voltage is boosted by the DC / DC converter 210.
After the time t3, the first switching element 112 is opened so that the voltage of the second battery 111 is not added to the voltage of the first battery 1 and the second state is set, and the boosting operation of the DC / DC converter 210 is performed. And the voltage Vs1 of the first battery 1 is applied to the load. The times t1, t2, and t3 are determined in advance according to the battery 1 and the load.

  As described above, by using the program unit 321, the series voltage source circuit 110 and the DC / DC converter 210 can be controlled without detecting the voltage Vs 1 of the first battery 1, and the detection unit for the voltage Vs 1 is unnecessary. Therefore, the configuration of the power supply device can be simplified.

Embodiment 3 FIG.
FIG. 4 is a configuration diagram showing the configuration of the power supply device according to the third embodiment. In FIG. 4, the power supply device 13 includes a series voltage source circuit 120. The series voltage source circuit 120 includes a second battery 111, a first switching element 112, and a first diode 113, and has the same components as the series voltage source circuit 110 of FIG. The order of connection between the first switching element 112 and the first switching element 112 is reversed. That is, the drain of the first switching element 112 is connected to the positive side of the second battery 111, and the second battery 111 and the first switching element 112 are connected in series. The anode of the first diode 113 is connected to the negative side of the second battery 111, the cathode of the first diode 113 is connected to the source side of the first switching element 112, and the second battery 111 and the first switching element 112 are connected in series. A first diode 113 is connected to the circuit in parallel. The negative side of the second battery 111 is connected to the positive side of the first battery 1, and the connection point between the second battery 111 and the first switching element 112 is connected to the positive input terminal 215 a of the DC / DC converter 210. . Since other configurations are the same as those of the first embodiment shown in FIG. 1, the same reference numerals are given to the corresponding components and the description thereof is omitted.

  This embodiment is different from the series voltage source circuit 110 shown in FIG. 1 in that the connection order of the second battery 111 and the first switching element 112 is changed, but the operation is the same. The control circuit 310 controls the operation of the series voltage source circuit 120 and the DC / DC converter 210 in accordance with the change in the voltage Vs1 of the first battery 1.

Embodiment 4 FIG.
FIG. 5 is a configuration diagram showing the configuration of the power supply device according to the fourth embodiment. In FIG. 5, the power supply device 14 includes a series voltage source circuit 130 and a control circuit 340. The series voltage source circuit 130 includes a charging circuit 134 as charging means. The control circuit 340 includes voltage detection means 311. The charging circuit 134 is configured by connecting a third switching element 135 as an output side opening / closing means and a third diode 136 as an output side one-way conduction means in series. In this embodiment, a MOSFET is used as the third switching element 135. The drain side of the third switching element 135 is connected to the positive side of the second battery 111, and the anode side of the third diode 136 is connected to the negative side of the second battery 111. A connection portion between the third switching element 135 and the third diode 136 is connected to the input terminal 215 a on the positive side of the DC / DC converter 210. Since other configurations are the same as those of the first embodiment shown in FIG. 1, the same reference numerals are given to the corresponding components and the description thereof is omitted.

  Next, the operation will be described. The basic operation of the control circuit 340 is the same as that of the control circuit 310 shown in FIG. That is, the control circuit 340 detects the voltage Vs1 of the first battery 1 by the voltage detection unit 311 and closes the first switching element 112 of the series voltage source circuit 130 depending on whether the voltage is higher or lower than the threshold value. The operation is performed, the DC / DC converter 210 is operated, both are operated, or both are not operated. That is, when the voltage Vs1 of the first battery 1 is higher than V2, the operation of closing the first switching element 112 and the operation of the DC / DC converter 210 are not performed. When the voltage Vs1 is higher than V1 and lower than V2, only the DC / DC converter 210 is operated. When V1 or less, the operation of closing the first switching element 112 and the operation of the DC / DC converter 210 are performed together.

Here, by closing the first switching element 112 and the third switching element 135 of the series voltage source circuit 130, a current flows through the following path.
First battery 1 → first switching element 112 → second battery 111 → third switching element 135 → DC / DC converter 210 (boost) → load 4 → DC / DC converter 210 → first battery 1.
By doing so, the voltage of the sum of the voltage of the first battery 1 and the voltage of the second battery 111 can be boosted using the series voltage source circuit 130.

When the first switching element 112 is not closed, there are two methods.
First, by closing the first switching element 112 and opening the third switching element 135, a current flows through the following path.
First battery 1 → first switching element 112 → third diode 136 → DC / DC converter 210 → load 4 → DC / DC converter 210 → first battery 1
The other is that the first switching element 112 is opened and the third switching element 135 is closed, whereby a current flows through the following path.
First battery 1 → first diode 113 → third switching element 135 → DC / DC converter 210 → load 4 → DC / DC converter 210 → first battery 1
By doing so, the voltage of the first battery 1 can be directly applied to the DC / DC converter 210 without closing the first switching element 112.

Further, by opening the first switching element 112 and the third switching element 135, a current flows through the following path.
First battery 1 → first diode 113 → second battery 111 → third diode 136 → DC / DC converter 210 → load 4 → DC / DC converter 210 → first battery 1
In this way, the second battery 111 can be charged by the charging circuit 134 instead of boosting the voltage Vs1 of the first battery 1.

Embodiment 5 FIG.
FIG. 6 is a configuration diagram showing the configuration of the power supply device according to the fifth embodiment. In FIG. 6, the power supply device 15 includes a series voltage source circuit 140 and a control circuit 350. The series voltage source circuit 140 includes a charging unit 144 as a charging unit and a charging DC / DC converter. The control circuit 350 includes voltage detection means 311. The series voltage source circuit 140 includes a capacitor 141 as a second DC voltage source and power storage means, and a charging circuit 144 as a charging means. The charging circuit 144 includes a second inductor 145 as a charging inductor, a fourth switching element 146 as a charging switching means, and a fourth diode 147 as a charging unidirectional conduction means. In this embodiment, a charging circuit 144 for charging the capacitor 141 is provided. In FIG. 6, a MOSFET is used as the fourth switching element 146.

  In the charging circuit 144, one terminal of the second inductor 145 and the drain of the fourth switching element 146 are connected, so that the second inductor 145 and the fourth switching element 146 are connected in series, and the second inductor 145 The other terminal is connected to the positive side of the first battery 1, and the source of the fourth switching element 146 and the negative side of the first battery 1 are connected. The anode of the fourth diode 147 is connected to the connection point between the second inductor 145 and the fourth switching element 146, and the cathode of the fourth diode 147 is connected to the connection point between the capacitor 141 and the first diode 113.

Next, the operation will be described. The control circuit 350 controls the series voltage source circuit 140 and the DC / DC converter 210 according to the voltage Vs1 of the first battery 1 detected by the voltage detection means 311 as in the control circuit 310 shown in FIG. Further, the control circuit 350 controls the charging circuit 144 as a charging unit and a charging DC / DC converter as follows, and charges the capacitor 141 as the second DC voltage source. First, when the fourth switching element 146 is closed, a current flows through the following path, and energy is accumulated in the second inductor 145.
First battery 1 → second inductor 145 → fourth switching element 146 → first battery 1
When the fourth switching element 146 is opened, a current flows through the following path, and the energy accumulated in the second inductor 145 is charged in the capacitor 141.
Second inductor 145 → fourth diode 147 → capacitor 141 → first switching element 112 → second inductor 145.
The first switching element 112 flows in this path regardless of whether it is closed or open. However, when the first switching element 112 is closed, the series voltage source circuit 140 is operated. Therefore, the series voltage source circuit 140 is operated more than the charging power of the capacitor 141. If the discharge power due to the operation is large, charging cannot be performed.

  As described above, the capacitor 141 can be charged using the second inductor 145. Note that the capacitor 141 and the charging circuit 144 can be used instead of the second battery 111 shown in FIGS.

Embodiment 6 FIG.
FIG. 7 is a configuration diagram showing the configuration of the power supply device according to the sixth embodiment. In FIG. 7, the power supply device 16 includes a series voltage source circuit 150 and a control circuit 360. The series voltage source circuit 150 includes a charging circuit 144. The control circuit 360 includes voltage detection means 311. In FIG. 7, the connection of the charging circuit 144 is different from that shown in FIG. That is, in the charging circuit 144, the second inductor 145 and the fourth switching element 146 are connected in series by connecting one terminal of the second inductor 145 and the drain of the fourth switching element 146, and the second inductor 145 is connected in series. One terminal of 145 is connected to a connection point between the first switching element 112 and the capacitor 141, and the source of the fourth switching element 146 and the negative side of the first battery 1 are connected. The anode of the fourth diode 147 is connected to the connection point between the second inductor 145 and the fourth switching element 146, and the cathode of the fourth diode 147 is connected to the connection point between the first diode 113 and the capacitor 141. The positive input terminal 215 a of the DC / DC converter 210 is connected to the connection point between the first diode 113 and the capacitor 141. Since other configurations are the same as those of the fifth embodiment shown in FIG. 6, the same reference numerals are given to the corresponding components and the description thereof is omitted.

Next, the operation will be described. The control circuit 360 controls the series voltage source circuit 150 and the DC / DC converter 210 in accordance with the voltage Vs1 of the first battery 1 detected by the voltage detection means 311 as in the control circuit 310 shown in FIG. The control circuit 360 controls the charging circuit 174 as follows to charge the capacitor 141.
First, when the first switching element 112 and the fourth switching element 146 are closed, a current flows through the following path, and energy is accumulated in the second inductor 145.
First battery 1 → first switching element 112 → second inductor 145 → fourth switching element 146 → first battery 1
When the fourth switching element 146 is opened, a current flows through the following path, and the energy stored in the second inductor 145 is charged in the second battery 111.
Second inductor 145 → fourth diode 147 → capacitor 141 → second inductor 145.

Note that current flows through this path regardless of whether the first switching element 112 is in a closed state or an open state. However, in this circuit system, when the first switching element 112 is closed, the first switching element 112 is connected between the first battery 1 and the DC / DC converter 210. When the discharge power due to the insertion of the second battery 111 is large, the second battery 111 cannot be charged.
As described above, the capacitor 141 can be charged using the second inductor 145.

Embodiment 7 FIG.
FIG. 8 is a configuration diagram showing the configuration of the power supply device according to the seventh embodiment. In FIG. 8, the power supply device 17 includes a series voltage source circuit 160 and a control circuit 370. The series voltage source circuit 160 has a charging circuit 174. The control circuit 370 has voltage detection means 311. The charging circuit 174 includes a transformer 175, a fifth switching element 176 as primary side switching means, and a fifth diode 177 as secondary side unidirectional conduction means. The transformer 175 has a primary winding 175a and a secondary winding 175b, and is wound around the common iron core in FIG. The control circuit 370 has voltage detection means 311. One terminal of the primary winding 175a is connected to the positive side of the first battery 1, the other terminal of the primary winding 175a is connected to the drain of the fifth switching element 176, and the source of the fifth switching element 176 is the first. Connected to the negative side of the battery 1. The secondary winding 175 b has one end connected to the connection point between the first switching element 112 and the capacitor 141, and the other end connected to the anode of the fifth diode 177. The cathode of the fifth diode 177 is connected to the connection point between the first diode 113 and the capacitor 141. Since other configurations are the same as those of the fifth embodiment shown in FIG. 6, the same reference numerals are given to the corresponding components and the description thereof is omitted.

  The control circuit 370 controls the series voltage source circuit 150 and the DC / DC converter 210 according to the voltage Vs1 of the first battery 1 detected by the voltage detection means 311 as in the control circuit 310 shown in FIG. Further, the control circuit 370 can charge the capacitor 141 from the first battery 1 via the transformer 175 by controlling the charging circuit 174 so that the fifth switching element 176 repeats opening and closing. Note that by providing the transformer 175, the number of elements through which current flows can be reduced, so that the capacitor 141 can be charged efficiently.

Embodiment 8 FIG.
FIG. 9 is a configuration diagram illustrating a configuration of a power supply device according to the eighth embodiment. In FIG. 9, the power supply device 18 includes a series voltage source circuit 170 and a control circuit 380. The control circuit 380 has voltage detection means 311. In FIG. 9, the charging circuit 174 has the same configuration as that shown in FIG. 8, but the connecting method of the charging circuit 174 is different. That is, one terminal of the primary winding 175 a is connected to the connection point between the first switching element 112 and the capacitor 141, and the other terminal of the primary winding 175 a is connected to the drain of the fifth switching element 176 to make the primary Winding 175 a and fifth switching element 176 are connected in series, and the source of fifth switching element 176 is connected to the negative side of first battery 1. Also, one terminal of the secondary winding 175b is connected to the other terminal of the primary winding 175a, the other terminal of the secondary winding 175b is connected to the anode of the fifth diode 177, and the cathode of the fifth diode 177. Is connected to a connection point between the first diode 113 and the capacitor 141. Since other configurations are the same as those of the fifth embodiment shown in FIG. 6, the same reference numerals are given to the corresponding components and the description thereof is omitted.

The control circuit 380 controls the series voltage source circuit 150 and the DC / DC converter 210 in accordance with the voltage Vs1 of the first battery 1 detected by the voltage detection means 311 as in the control circuit 310 shown in FIG. Further, the control circuit 380 controls the charging circuit 174 as follows. In the charging circuit 174, the first switching element 112 and the fifth switching element 176 are closed, and then the fifth switching element 176 is opened. Note that after the fifth switching element 176 is opened, the first switching element 112 may be closed or open.
In this circuit system, there is always time to close the first switching element 112, and the second battery 111 is inserted between the first battery 1 and the DC / DC converter 210. When the discharge power is larger than the charge power, the second battery 111 cannot be charged.
As described above, the first switching element 112 and the fifth switching element 176 are repeatedly opened and closed, so that the capacitor 141 can be charged from the first battery 1 via the primary winding 175a and the secondary winding 175b. .

Embodiment 9 FIG.
FIG. 10 is a configuration diagram illustrating a configuration of the power supply device according to the ninth embodiment. In this embodiment, the power supply device 11 of FIG. 1 is replaced with a synchronous rectification power supply device 19. In FIG. 10, the power supply device 19 includes a series voltage source circuit 180, a DC / DC converter 220 as a DC-DC converter, and a control circuit 390. The control circuit 390 includes voltage detection means 311. The series voltage source circuit 180 includes a unidirectional conduction means and a sixth switching element 183 as a semiconductor switching element. As the sixth switching element 183, a MOSFET having a parasitic diode connected in parallel similar to the first switching element 112 in FIG. 1 is used. The source of the sixth switching element 183 is connected to the drain of the first switching element 112, and the drain of the sixth switching element 183 is connected to the positive side of the second battery 111. The first switching element 112 and the sixth diode 183 are switching means in the present invention. The first inductor 211 as the boosting inductor, the second switching element 212 as the boosting switching means, and the seventh switching element 223 as the boosting unidirectional conduction means are the boosting circuit in the present invention.

  The DC / DC converter 220 includes a first inductor 211, a second switching element 212, a seventh switching element 223, positive and negative input terminals 225a and 225b, and positive and negative output terminals 226a and 226b. One terminal of the first inductor 211 and the drain of the second switching element 212 are connected to form a series circuit, and this series circuit is connected to the input terminals 225a and 225b on both the positive and negative sides. The source of the seventh switching element 223 is connected to the connection point between the other terminal of the first inductor 211 and the second switching element 212, and the output terminal 226 a is connected to the drain of the seventh switching element 223. Further, the input terminal 225b and the output terminal 226b are directly connected. Since other configurations are the same as those of the first embodiment shown in FIG. 1, the same reference numerals are given to the corresponding components and the description thereof is omitted.

  The control circuit 390 controls the series voltage source circuit 180 and the DC / DC converter 220 in accordance with the voltage Vs1 of the first battery 1 detected by the voltage detection means 311 as in the control circuit 310 shown in FIG. . The sixth switching element 183 corresponds to the first diode 113 in FIG. 1, the seventh switching element 223 corresponds to the second diode 213, and the sixth switching element 183 includes the first switching element 112 in FIG. The seventh switching element 223 is closed or conductive for a time corresponding to the open time, and the seventh switching element 223 is closed or conductive for a time corresponding to the time when the second switching element 212 of FIG. 1 is open. Since the current flows through the sixth switching element 183 and the seventh switching element 223 with less loss than the first diode 113 and the second diode 213, the efficiency of the power supply device can be increased.

  Further, by replacing the first diodes 113 and 213 in each of the above embodiments with a switching element having a parasitic diode or a switching element and a diode connected in parallel to the switching element, synchronous rectification can be performed, and the power Efficiency can be improved.

Embodiment 10 FIG.
FIG. 11 is a configuration diagram illustrating a configuration of the power supply device according to the tenth embodiment. In FIG. 11, the power supply device 20 includes a control circuit 400, an open / close switch 511 as a first bypass switch, and an open / close switch 512 as a second bypass switch. The open / close switch 511 is connected to a connection portion between the series voltage source circuit 110 and the positive side of the first battery 1, and a connection portion between the series voltage source circuit 110 and the positive side input terminal 215 a of the DC / DC converter 210. Yes. The open / close switch 512 is connected to a connection portion between the series voltage source circuit 110 and the positive input terminal 215 a of the DC / DC converter 210, and a connection portion between the positive output terminal 216 a of the DC / DC converter 210 and the load 4. It is connected. The control circuit 400 closes the open / close switch 511 or the open / close switch 512 when the series voltage source circuit 110 or the DC / DC converter 210 is not operated.

  By closing the open / close switch 511, current can flow from the positive side of the first battery 1 to the DC / DC converter 210 without passing through the series power supply circuit 110. By closing the open / close switch 512, the series voltage source circuit 110 does not substantially pass through the DC / DC converter 210 (although it passes through the negative input terminal 215b and the output terminal 216b in terms of shape). A current can flow to the load 4. The open / close switch 511 is closed when the series voltage source circuit 110 is not operated, and the open / close switch 512 is closed when the DC / DC converter 210 is not operated. Thereby, the bypass voltage flows through the open / close switches 511 and 512 without substantially passing through the series voltage source circuit 110 and the DC / DC converter 210, so that the resistance loss in the series voltage source circuit 110 and the DC / DC converter 210 is reduced. It can be lost. When the series voltage source circuit 110 or the DC / DC converter 210 is not operated, it is possible to achieve high efficiency by finely controlling.

Embodiment 11 FIG.
FIG. 12 is a configuration diagram showing the configuration of the power supply device according to the eleventh embodiment. In FIG. 12, the power supply device 21 includes a control circuit 410 and an open / close switch 610 as a third bypass switch. The open / close switch 610 is connected to a connection part between the series voltage source circuit 110 and the positive side of the first battery 1, and a connection part between the positive output terminal 216 a of the DC / DC converter 210 and the load 4. The control circuit 410 closes the open / close switch 610 when both the series voltage source circuit 110 and the DC / DC converter 210 are not operated. By closing the open / close switch 610, the voltage of the first battery 1 is bypassed from the positive side of the first battery 1 to the load 4 without substantially passing through the series voltage source circuit 110 and the DC / DC converter 210. It can be applied to the load 4. This eliminates resistance loss when passing through the series voltage source circuit 110 and the DC / DC converter 210, and increases the efficiency when both the series voltage source circuit 110 and the DC / DC converter 210 are not operated. it can.

  In each of the above embodiments, the same effect can be obtained even if the capacitor 141 is used instead of the second battery 111, or the second battery 111 is used instead of the capacitor 141. Note that the charging circuit is not essential. A detachable primary battery or secondary battery can also be used without providing a charging circuit.

1 first battery, 4 loads, 11, 12, 13, 14, 15, 16 power supply device,
17, 19, 20, 21 power supply device, 110 series voltage source circuit,
111 second battery, 112 first switching element, 113 first diode,
120, 130 series voltage source circuit, 135 third switching element,
136 third diode, 140 series voltage source circuit, 141 capacitor,
144 charging circuit, 145 second inductor, 146 fourth switching element,
147 4th diode, 150,160 series voltage source circuit, 174 charging circuit,
175 transformer, 175a primary winding, 175b secondary winding,
176 fifth switching element, 177 fifth diode, 180 series voltage source circuit,
183 sixth switching element, 210 DC / DC converter,
211 first inductor, 212 second switching element, 213 second diode,
215a, 215b input terminal, 216a, 216b output terminal,
220 DC / DC converter, 223 7th switching element,
225a, 225b input terminal, 226a, 226b output terminal, 310 control circuit,
311 voltage detection means, 320 control circuit, 321 program control means,
330, 340, 350, 360, 370, 380, 390 control circuit,
400, 410 Control circuit, 511, 512, 610 Open / close switch.

Claims (14)

A power supply device having a first DC voltage source, a series voltage source device, a DC-DC converter, and a control device,
The series voltage source device has a second DC voltage source and switching means,
The DC-DC converter has an input terminal, an output terminal, and a booster circuit. The booster circuit boosts a DC voltage input to the input terminal and outputs the boosted voltage from the output terminal. Is designed to conduct between the input terminal and the output terminal,
The input terminal of the DC-DC converter is connected to the first DC voltage source via the series voltage source device, and a load is connected to the output terminal,
The control device controls the switching means so that the first DC voltage source and the second DC voltage source are connected in series, and the voltage of the first DC voltage source and the second DC voltage source are The booster circuit switches between a first state in which a voltage added to the input terminal is applied to the input terminal and a second state in which the voltage of the first DC voltage source is independently applied to the input terminal. A power supply device that controls the operation of the machine. The control device includes voltage detection means for detecting the voltage of the first DC voltage source, and when the voltage of the first DC voltage source is less than a first value, the switching means is set. The first DC voltage source and the second DC voltage source are controlled to be in the first state and the booster circuit is operated to be higher than the first value and higher than the first value. When the value is less than the second value, the first DC voltage source and the second DC voltage source are set to the second state, the booster circuit is operated, and the second DC value is greater than or equal to the second value. 2. The power supply according to claim 1, wherein the first DC voltage source and the second DC voltage source are set to the second state and the operation of the booster circuit is stopped. apparatus. The control device includes program control means, and the program control means controls the switching means from a predetermined time point to before the first time to control the first DC voltage source and the first voltage source. And the second DC voltage source is set to the second state and the step-up circuit is not operated, and the first DC voltage source and the second DC voltage source are not operated until the second time is reached. The DC voltage source is set to the first state and the booster circuit is operated, and after the second time, the first DC voltage source and the second DC voltage source are set to the second state. The power supply device according to claim 1, wherein: The switching means has an opening / closing means and a one-way conduction means,
The open / close means is connected in series with the second DC voltage source and constitutes a series circuit with the second DC voltage source,
The one-way conduction means is connected in parallel with the series circuit, and is configured to allow a current to flow by bypassing the series circuit when the switching means is open,
The series circuit is connected in series with the first DC voltage source;
4. The control device according to claim 1, wherein the control device controls opening / closing of the opening / closing means to switch between the first state and the second state. 5. Power supply. 5. The power supply device according to claim 4, wherein the one-way conducting means is a semiconductor switching element, and is non-conductive when the opening / closing means is closed, and is conductive when opened. . The booster circuit includes a boosting inductor, a boosting switching unit, and a boosting one-way conduction unit, and a series circuit in which the boosting inductor and the boosting switching unit are connected in series is connected between the input terminals. Connected to one of the output terminals via the boosting unidirectional conducting means, and a connecting portion between the boosting inductor and the boosting switching means.
The voltage generated in the boosting inductor by opening / closing the boosting switching means is closed when the boosting one-way conduction means is closed in synchronism with the opening of the boosting switching means, and is opened in synchronism with the closing circuit. The power supply apparatus according to claim 1, wherein the power supply apparatus outputs to a terminal. The second DC voltage source is a chargeable / dischargeable power storage means,
The power supply apparatus according to claim 1, wherein the series voltage source device includes a charging unit that charges the power storage unit. The power storage device according to claim 7, wherein the power storage unit is a secondary battery. The power supply device according to claim 7, wherein the power storage unit is a capacitor. The charging means is a charging DC / DC converter, and the charging DC / DC converter charges the power storage means by converting the voltage of the first DC voltage source and applying it to the power storage means. The power supply device according to claim 7, wherein: The charging DC / DC converter includes a charging inductor, a charging switching unit, and a charging one-way conduction unit, and a series circuit in which the charging inductor and the charging switching unit are connected in series includes The power storage means connected in parallel to the first DC voltage source and applying a voltage generated in the charging inductor by opening and closing the charge switching means to the power storage means via the charging one-way conduction means. The power supply device according to claim 10, wherein the power supply device is charged. The charging DC / DC converter includes a transformer, a primary side switching unit, and a secondary side one-way conduction unit. The transformer includes a primary winding and a secondary winding, and the primary winding is the above-described primary winding. The primary side switching means is connected in parallel to the first DC voltage source, the secondary winding is connected in parallel to the power storage means via the secondary side one-way conduction means, and the primary side switching is performed. 11. The power storage means is charged by applying a voltage generated in the secondary winding by opening / closing of the means to the power storage means through the secondary side one-way conduction means. The power supply device described in 1. The charging means is an output side opening / closing means and an output side one-way conduction means connected in series,
A series circuit of the output side switching means and the output side one-way conduction means is connected to the second DC voltage source, and the DC-DC converter is connected via the output side switching means and the series voltage source device. Connected to the first DC voltage source;
When the opening / closing means is opened, the output-side opening / closing means is opened to apply the voltage of the first DC voltage source to the power storage means to charge the power storage means. Item 8. The power supply device according to Item 7. Having at least one of first, second and third bypass switches,
The first bypass switch enables the voltage of the first DC voltage source to be applied to the DC-DC converter without passing through the series voltage source device.
The second bypass switch allows the voltage of the first DC voltage source or the voltage of the first DC voltage source and the voltage of the second DC voltage source without passing through the DC-DC converter. The added voltage can be applied to the load,
The third bypass switch enables the voltage of the first DC voltage source to be applied to the load without passing through the series voltage source device and the DC-DC converter. The power supply device according to any one of claims 1 to 13.

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