JP2013183562A - Power supply device, portable terminal device, power supply device control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply device that is capable of, in a charge system, continuing to supply electric power charged in a secondary battery to a load for a longer time with less components.SOLUTION: A power supply device includes a bidirectional DC-DC converter 4, an electric path switching part 11, and a control part 12 for controlling the bidirectional DC-DC converter 4 and the electric path switching part 11. When no external power supply is connected, the control part 12 steps up electric power of a secondary battery 10 and supplies the electric power to a load by causing the bidirectional DC-DC converter 4 to operate and causing the electric path switching part 11 to operate to connect a first input terminal TB 11a to an output terminal TB 11c, or supplies the electric power of the secondary battery 10 to the load by causing the bidirectional DC-DC converter 4 to stop its operation and causing the electric path switching part 11 to operate to connect a second input terminal TB 11b to the output terminal TB 11c. When an external power supply is connected, the control part 12 steps down electric power of the external power supply and supplies the electric power to the secondary battery 10 by causing the bidirectional DC-DC converter 4 to operate.

Description

  The present invention relates to a power supply device, a portable terminal device, a control method for the power supply device, and a program.

  In order to efficiently charge the secondary battery, a power supply device using a DC (Direct Current) -DC converter is employed in the electric device using the secondary battery.

  Here, Patent Document 1 describes a charge / discharge circuit for a secondary battery that can charge the secondary battery with an external power source and supply power from the secondary battery to an external device. Further, Patent Document 2 describes a bidirectional converter capable of switching current input / output bidirectionally between a power input terminal or load and a secondary battery. Patent Document 3 describes an energy storage system that can directly supply DC power between a battery and a DC load without converting from an AC (Alternating Current) power source to a DC power source.

JP 2007-336698 A JP 2008-035675 A JP 2011-120447 A

  As described above, there is a power supply device using a DC-DC converter. However, in a power supply device that uses a DC-DC converter to charge a secondary battery or supply power to a load, the secondary device can be configured with a small number of components. There is a need for a power supply device that can continue to supply power charged in a battery to a load for a longer time.

  The objective of this invention is providing the power supply device, the portable terminal device, the control method of a power supply device, and a program which solve the subject mentioned above.

  In order to solve the above problems, a power supply device according to the present invention includes a bidirectional DC-DC converter that boosts and outputs the power of a secondary battery, or steps down and outputs the power of an external power supply, and a bidirectional DC. A first input terminal connected to the boost output terminal of the DC converter and an external power source, a second input terminal connected to the step-down output terminal of the bidirectional DC-DC converter and the secondary battery, and a load An electric line switching unit that has an output terminal to be connected, connects one of the first input terminal and the second input terminal to the output terminal, and switches a power supply path to the load; A control unit that controls the bidirectional DC-DC converter and the electric circuit switching unit, and the control unit operates the bidirectional DC-DC converter when the external power source is not connected, and the first input terminal Operate the circuit switching unit to connect the The power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is stopped, and the electric circuit switching unit is operated so that the second input terminal is connected to the output terminal. When the power of the secondary battery is supplied to the load and an external power supply is connected, the bidirectional DC-DC converter is operated to reduce the power of the external power supply and supply it to the secondary battery.

  A portable terminal device according to the present invention includes the power supply device described above.

  The control method of the power supply apparatus according to the present invention operates the bidirectional DC-DC converter when the external power supply is not connected, and connects the boosted output terminal of the bidirectional DC-DC converter to the external power supply. The electric circuit switching unit is operated so that the input terminal of 1 is connected to the output terminal connected to the load, and the power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is performed. The electric circuit switching unit is operated so that the second input terminal connected to the step-down output terminal of the bidirectional DC-DC converter and the secondary battery is connected to the output terminal, and the power of the secondary battery is reduced. When the external power supply is connected to the load, the bidirectional DC-DC converter is operated to reduce the power of the external power supply and supply it to the secondary battery.

  A program according to the present invention operates a bidirectional DC-DC converter when an external power source is not connected to a computer, and is connected to a boost output terminal of the bidirectional DC-DC converter and an external power source. The circuit switching unit is operated so that the input terminal of the battery is connected to the output terminal connected to the load, and the power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is stopped. In addition, the electric circuit switching unit is operated so that the second input terminal connected to the step-down output terminal of the bidirectional DC-DC converter and the secondary battery is connected to the output terminal, and the power of the secondary battery is loaded. When the external power supply is connected, the bidirectional DC-DC converter is operated to function as control means for reducing the power of the external power supply and supplying it to the secondary battery.

  As described above, the present invention can supply the power of the secondary battery to the load or boost the power of the secondary battery to the load when the external power source is not connected. Since the power of the external power can be stepped down and supplied to the secondary battery, the power of the secondary battery can be continuously supplied to the load for a longer time.

It is a figure which shows an example of the circuit structure of the power supply device which concerns on one Embodiment. It is a figure which shows an example of the circuit structure of the modulation control part 4a. 3 is a diagram illustrating an example of a circuit configuration of a control unit 12. FIG. It is a figure which shows an example of each state A1-A5 of a power supply device. It is a figure which shows the relationship in which the state of a power supply device changes to each state A1-A5. It is a timing chart until the state of a power supply device changes from state A1 to state A5 through state A2. It is a timing chart until the state of a power supply device changes from state A2 to state A4 through state A3. It is a figure which shows the supply path | route of the electric power in state A1. It is a figure which shows the supply path | route of the electric power in state A2. It is a figure which shows the supply path | route of the electric power in state A3. It is a figure which shows the supply path | route of the electric power in state A4. It is a figure which shows the supply path | route of the electric power in state A5.

  FIG. 1 shows an example of a circuit configuration of a power supply device according to an embodiment. The power supply device according to the present embodiment is a device that supplies power supplied from a secondary battery or an external power supply to a load.

  The power supply device according to the present embodiment includes an external power supply terminal 1, a diode 2, a bypass capacitor 3, a bidirectional DC-DC converter 4, a secondary battery 10, an electric circuit switching unit 11, and a control unit 12. The bidirectional DC-DC converter 4 includes a modulation control unit 4a, field effect transistors 5 and 6, an inductor 7, a smoothing capacitor 8, and a resistor 9. The bidirectional DC-DC converter 4 includes a modulation control unit 4a, field effect transistors 5 and 6, an inductor 7, a smoothing capacitor 8, and a resistor 9. The electric circuit switching unit 11 includes a low-loss regulator 111 and a field effect transistor 112.

  An external power supply is connected to the external power supply terminal 1. The external power supply terminal 1 is connected to the anode terminal of the diode 2 and the control unit 12.

  The diode 2 outputs the power supplied from the external power supply terminal 1 to the terminal TB41 of the bidirectional DC-DC converter 4. The diode 2 prevents the power output from the terminal TB41 of the bidirectional DC-DC converter 4 from flowing to the external power supply terminal 1. The anode terminal of the diode 2 is connected to the external power supply terminal 1. The cathode terminal of the diode 2 is connected to the terminal TB41 of the bidirectional DC-DC converter 4, the input terminal TB11a (first input terminal) of the electric circuit switching unit 11, and one end of the bypass capacitor 3.

  The bypass capacitor 3 prevents the voltage of the DC power supply from fluctuating when the power supply device operates. One end of the bypass capacitor 3 is connected to the cathode terminal of the diode 2, the terminal TB 41 of the bidirectional DC-DC converter 4, and the input terminal TB 11 a of the electric circuit switching unit 11. The other end of the bypass capacitor 3 is connected to the ground.

  The bidirectional DC-DC converter 4 operates as a step-down DC-DC converter and a step-up DC-DC converter according to a control signal output from the control unit 12. The diode TB, the bypass capacitor 3, and the input terminal TB11a of the electric circuit switching unit 11 are connected to the terminal TB41 of the bidirectional DC-DC converter 4. The input terminal TB11b (second input end) of the electric circuit switching unit 11 is connected to the terminal TB42 of the bidirectional DC-DC converter 4. The secondary battery 10 is connected to the terminal TB43 of the bidirectional DC-DC converter 4. Further, the signal output terminal of the control unit 12 is connected to the signal input terminal of the bidirectional DC-DC converter 4.

  The modulation control unit 4a of the bidirectional DC-DC converter 4 is based on the voltage of the terminal TB41, the current flowing to the secondary battery 10, the terminal voltage of the secondary battery 10, and the control signal output from the control unit 12. Pulse width modulation control of the field effect transistors 5 and 6 is performed. The field effect transistors 5 and 6 of the bidirectional DC-DC converter 4 are switched on / off based on a pulse width modulation control signal from the modulation control unit 4a. The inductor 7 of the bidirectional DC-DC converter 4 boosts the power from the secondary battery 10. The inductor 7 of the bidirectional DC-DC converter 4 smoothes the power from the external power source. The smoothing capacitor 8 of the bidirectional DC-DC converter 4 smoothes the pulsating flow. The resistor 9 of the bidirectional DC-DC converter 4 is provided to detect the current flowing through the secondary battery 10 using the potential difference of the resistor 9.

  The secondary battery 10 is a battery that can be used repeatedly by storing electricity so that it can be used as a battery. The positive electrode of the secondary battery 10 is connected to the terminal TB43 of the bidirectional DC-DC converter 4. The negative electrode of the secondary battery 10 is grounded.

  The electric circuit switching unit 11 switches on / off of the low-loss regulator 111 and the field effect transistor 112 in accordance with a control signal output from the control unit 12, and supplies electric power input from the input terminal TB11a or the input terminal TB11b. Output to the output terminal TB11c (output terminal).

  The control unit 12 controls the bidirectional DC-DC converter 4 and the electric circuit switching unit 11. More specifically, the control unit 12 operates the bidirectional DC-DC converter 4 and connects the input terminal TB11a to the output terminal TB11c when the external power supply is not connected to the external power supply terminal 1. The electric circuit switching unit 11 is operated to increase the power of the secondary battery 10 and supply it to the load. In addition, when the external power supply is not connected to the external power supply terminal 1, the control unit 12 stops the operation of the bidirectional DC-DC converter 4 and connects the input terminal TB11b to the output terminal TB11c. 11 is operated to supply the power of the secondary battery 10 to the load. Further, when an external power supply is connected to the external power supply terminal 1, the control unit 12 operates the bidirectional DC-DC converter 4 to step down the power of the external power supply and supply it to the secondary battery 10.

  For example, the control unit 12 stops the operation of the bidirectional DC-DC converter 4 when the external battery is not connected to the external power supply terminal 1 and the battery voltage of the secondary battery 10 is equal to or higher than a predetermined value. The electric circuit switching unit 11 is operated so as to connect the input terminal TB11b to the output terminal TB11c, and the electric power of the secondary battery 10 is supplied to the load.

  For example, when the external power supply is not connected to the external power supply terminal 1, the control unit 12 operates the bidirectional DC-DC converter 4 when the battery voltage of the secondary battery 10 is less than a predetermined value, The electric circuit switching unit 11 is operated so as to connect the input terminal TB11a to the output terminal TB11c, and the power of the secondary battery 10 is boosted and supplied to the load.

  Further, for example, when the external power supply is connected to the external power supply terminal 1, the control unit 12 operates the bidirectional DC-DC converter 4 when the battery voltage of the secondary battery 10 is not the value at the time of full charge. In addition, the electric circuit switching unit 11 is operated so as to connect the input terminal TB11a to the output terminal TB11c, the electric power of the external power supply is stepped down and supplied to the secondary battery 10, and the electric power of the external power supply is supplied to the load. .

  Further, for example, when the external power supply is connected to the external power supply terminal 1, the control unit 12 operates the bidirectional DC-DC converter 4 when the battery voltage of the secondary battery 10 is not the value at the time of full charge. At the same time, the electric circuit switching unit 11 is operated so as to connect the input terminal TB11b to the output terminal TB11c, and the electric power of the external power source is stepped down and supplied to the secondary battery 10 and the load.

  In addition, for example, the control unit 12 determines that the battery voltage of the secondary battery 10 is the minimum voltage necessary for the bidirectional DC-DC converter 4 to operate normally when an external power supply is not connected to the external power supply terminal 1. When the value is less than the value, the operation of the bidirectional DC-DC converter 4 is stopped, and the electric circuit switching unit 11 is operated so as to connect the input terminal TB11a to the output terminal TB11c, thereby stopping the supply of power to the load. .

  FIG. 2 shows an example of a circuit configuration of the modulation control unit 4a. The modulation control unit 4a includes an oscillation circuit 41, a pulse width modulation circuit 42, a charge control circuit 43, error amplifiers 44, 45, 46, an operation switching circuit 47, and a switch 48.

  The oscillation circuit 41 generates and outputs a continuous pulse wave that repeats at a predetermined cycle. The output terminal of the oscillation circuit 41 is connected to the pulse wave input terminal of the pulse width modulation circuit 42. For example, the frequency of the signal output from the oscillation circuit 41 is the modulation frequency of the pulse width in the pulse width modulation circuit 42.

  The pulse width modulation circuit 42 is a circuit that modulates the duty ratio of the pulse wave output from the oscillation circuit 41 and outputs it to the field effect transistors 5 and 6. The pulse wave input terminal of the pulse width modulation circuit 42 is connected to the output terminal of the oscillation circuit 41. The control signal input terminal of the pulse width modulation circuit 42 is connected to the output terminal of the switch 48. Then, the pulse width modulation circuit 42 receives a signal output from the charge control circuit 43 or the error amplifier 46 as an input signal. The pulse width modulation circuit 42 modulates the duty ratio of the pulse wave output from the oscillation circuit 41 according to the input signal, and outputs the modulated signal to the field effect transistors 5 and 6. At that time, the pulse width modulation circuit 42 inverts the phase of the pulse wave output to the field effect transistor 5 and the phase of the pulse wave output to the field effect transistor 6.

  The charge control circuit 43 is a circuit that outputs a signal output from the error amplifier 44 or the error amplifier 45 to the pulse width modulation circuit 42. The charging control circuit 43 has two input terminals, and each of the input terminals is connected to the output terminals of the error amplifier 44 and the error amplifier 45, respectively. The output terminal of the charge control circuit 43 is connected to the input terminal of the switch 48.

  The error amplifier 44 is an element that amplifies and outputs the difference between the current value flowing through the resistor 9 and the reference current value Iref when the secondary battery 10 is charged with constant current. The differential input terminal of the error amplifier 44 is connected to both ends of the resistor 9, and a predetermined potential corresponding to the product of the resistance value of the resistor 9 and the reference current value Iref is supplied to the other input terminal. Has been. The output terminal of the error amplifier 44 is connected to the input terminal of the charge control circuit 43.

  The error amplifier 45 is an element that amplifies and outputs the difference between the battery voltage Vbat of the secondary battery and the reference voltage value Vref1 indicating the charging target voltage when the secondary battery 10 is charged at a constant voltage. One input terminal (inverted input terminal) of the error amplifier 45 is connected to the secondary battery 10, and the reference voltage value Vref1 is supplied to the other input terminal (non-inverted input terminal). The output terminal of the error amplifier 45 is connected to the input terminal of the charge control circuit 43.

  The error amplifier 46 is an element that amplifies and outputs the difference between the voltage value boosted and output by the bidirectional DC-DC converter 4 and the voltage value Vref2 to be supplied to the load. For example, the voltage value Vref2 indicates the target voltage of the voltage that the bidirectional DC-DC converter 4 boosts and outputs. One input terminal (inverted input terminal) of the error amplifier 46 is connected to the drain terminal (when an external power supply is connected) of the field effect transistor 5, and the other input terminal (non-inverted input terminal) has a reference voltage value. Vref2 is supplied. The output terminal of the error amplifier 46 is connected to the input terminal of the switch 48.

  The operation switching circuit 47 switches the connection destination of the switch 48 so as not to be connected to the charge control circuit 43 side, the error amplifier 46 side, or any side in accordance with the control signal output from the control unit 12. The input terminal of the operation switching circuit 47 is connected to the logic circuits 125 and 126 of the control unit 12. The output terminal of the operation switching circuit 47 is connected to the control signal input terminal of the switch 48. When such an operation switching circuit 47 boosts and outputs the voltage to the bidirectional DC-DC converter 4, the switch 48 is set to the error amplifier 46 side and the voltage is lowered to the bidirectional DC-DC converter 4 for output. The switch 48 is set to the charge control circuit 43 side.

  The switch 48 includes two input terminals, an output terminal, and a control input terminal, and alternatively connects the two input terminals to the output terminal according to a signal supplied to the control input terminal. Each of the input terminals of the switch 48 is connected to the output terminal of the charge control circuit 43 or the output terminal of the error amplifier 46. The output terminal of the switch 48 is connected to the control signal input terminal of the pulse width modulation circuit 42. The control signal input terminal of the switch 48 is connected to the output terminal of the operation switching circuit 47.

  FIG. 3 shows an example of the circuit configuration of the control unit 12. The control unit 12 includes an external voltage detection circuit 121, a battery low voltage detection circuit 122, a UVLO (Under Voltage Lock Out) voltage detection circuit 123, logic circuits 124 to 127, and a delay circuit 128. .

  The external voltage detection circuit 121 is a circuit that detects the voltage value of the external power supply. The input terminal of the external voltage detection circuit 121 is connected to the external power supply terminal 1 and the anode terminal of the diode 2. The output terminal of the external voltage detection circuit 121 is connected to the input terminals of the logic circuits 125 and 126. When the external voltage detection circuit 121 detects the voltage value of the external power supply, it outputs a HIGH signal to the logic circuit 125 and the logic circuit 126. Further, the external voltage detection circuit 121 outputs a LOW signal to the logic circuit 125 and the logic circuit 126 when the voltage value of the external power supply is not detected.

  When the voltage value Vbat of the secondary battery 10 becomes smaller than the minimum voltage value (Va: load stable minimum voltage value) at which the load can be stably operated, the battery low voltage detection circuit 122 detects this. It is a circuit to detect. For example, the battery low voltage detection circuit 122 determines the load stable minimum voltage value Va as a threshold voltage (first threshold voltage), and determines whether the voltage value Vbat of the secondary battery 10 is less than the load stable minimum voltage value Va. Based on whether or not, a LOW signal or a HIGH signal is output. Note that the load stable minimum voltage value Va does not limit the actual operation of the load when the voltage value Vbat of the secondary battery 10 becomes less than the load stable minimum voltage value Va. The input terminal of the battery low voltage detection circuit 122 is connected to the secondary battery 10. Further, the output terminal of the battery low voltage detection circuit 122 is connected to the input terminals of the logic circuits 125 and 127. The battery low voltage detection circuit 122 outputs a LOW signal to the logic circuits 124 and 127 when Vbat is less than Va. The battery low voltage detection circuit 122 outputs a HIGH signal to the logic circuits 124 and 127 when Vbat is equal to or higher than Va.

  The UVLO voltage detection circuit 123 is a circuit that detects when the voltage value Vbat of the secondary battery 10 is smaller than the minimum voltage value UVLO that allows the bidirectional DC-DC converter 4 to operate stably. It is. For example, the UVLO voltage detection circuit 123 determines the minimum voltage value UVLO as a threshold voltage (second threshold voltage), and LOW based on whether or not the voltage value Vbat of the secondary battery 10 is less than the minimum voltage value UVLO. Or HIGH signal is output. The input terminal of the UVLO voltage detection circuit 123 is connected to the secondary battery 10. The output terminal of the UVLO voltage detection circuit 123 is connected to the input terminal of the logic circuit 124. The UVLO voltage detection circuit 123 outputs a LOW signal to the logic circuit 124 when Vbat is less than UVLO. The UVLO voltage detection circuit 123 outputs a HIGH signal to the logic circuit 124 when Vbat is equal to or higher than UVLO. Here, the value of UVLO is set to a value smaller than the value of Va.

  The logic circuit 124 is a kind of digital logic circuit. The input terminal of the logic circuit 124 is connected to the output terminal of the battery low voltage detection circuit 122 and the output terminal of the UVLO voltage detection circuit 123. The output terminal of the logic circuit 124 is connected to the input terminal of the logic circuit 126. Then, the logic circuit 124 receives signals output from the battery low voltage detection circuit 122 and the UVLO voltage detection circuit 123 as input signals. The logic circuit 124 outputs a LOW signal to the logic circuit 126 when only one of the input signals is HIGH. In addition, the logic circuit 124 outputs a HIGH signal to the logic circuit 126 when both input signals are HIGH or LOW.

  The logic circuit 125 is a kind of digital logic circuit. The input terminal of the logic circuit 125 is connected to the output terminal of the external voltage detection circuit 121 and the output terminal of the battery low voltage detection circuit 122. The output terminal of the logic circuit 125 is connected to the input terminal of the operation switching circuit 47 of the modulation control unit 4a. Then, the logic circuit 125 receives signals output from the external voltage detection circuit 121 and the battery low voltage detection circuit 122 as input signals. When both input signals are LOW, the logic circuit 125 outputs a HIGH MODE signal to the modulation control unit 4a. Further, when one or both of the input signals are HIGH, the logic circuit 125 outputs a LOW MODE signal to the modulation control unit 4a. Here, the MODE signal is a signal serving as a trigger for switching the switch 48 of the modulation control unit 4a.

  The logic circuit 126 is a kind of digital logic circuit. The input terminal of the logic circuit 126 is connected to the output terminal of the external voltage detection circuit 121 and the output terminal of the logic circuit 124. The output terminal of the logic circuit 126 is connected to the input terminal of the operation switching circuit 47 of the modulation control unit 4a. Then, the logic circuit 126 receives signals output from the external voltage detection circuit 121 and the logic circuit 124 as input signals. Then, when the input signal received from the external voltage detection circuit 121 is LOW and the input signal received from the logic circuit 124 is HIGH, the logic circuit 126 outputs a HIGH SHTDWN signal to the modulation control unit 4a. The logic circuit 126 outputs a LOW SHTDWN signal to the modulation control unit 4a when both of the input signals are LOW or when the input signal received from the external voltage detection circuit 121 is HIGH. Here, the SHTDWN signal is a signal that performs on / off control of the function of the bidirectional DC-DC converter 4.

  The logic circuit 127 is a kind of digital logic circuit. The input terminal of the logic circuit 127 is connected to the output terminal of the battery low voltage detection circuit 122. The output terminal of the logic circuit 127 is connected to the input terminal of the delay circuit 128. Then, the logic circuit 127 receives a signal output from the battery low voltage detection circuit 122 as an input signal. Then, the logic circuit 127 outputs a signal obtained by reversing the logic level of the input signal to the delay circuit 128.

  The delay circuit 128 is a circuit that slightly delays the signal output from the logic circuit 127 and outputs the signal to the electric circuit switching unit 11 as the SWCNT signal. The input terminal of the delay circuit 128 is connected to the output terminal of the logic circuit 127. The output terminal of the delay circuit 128 is connected to the control signal input terminal of the low-loss regulator 111 in the power supply switching circuit 11 and the gate terminal of the field effect transistor 112. Here, the SWCNT signal is a signal for controlling the operation of the electric circuit switching unit 11.

  FIG. 4 shows an example of each state A1 to A5 of the power supply device. According to the circuit configuration of the control unit 12 shown in FIG. 3, as shown in FIG. 4, the control unit 12 has no power supply from the external power source (the external power source is “none”), and the battery voltage is Vbat ≧ When the state is Va state A1, a HIGH SHTDWN signal is output to the modulation control unit 4a to control the operation of the bidirectional DC-DC converter 4 to OFF. Then, the control unit 12 outputs a LOW SWCNT signal to the electric circuit switching unit 11 to control the low loss regulator 111 to be turned off and the field effect transistor 112 to be turned on. Further, according to the configuration of the control unit 12 shown in FIG. 3, the control unit 12 has no power supply from the external power source (external power source is “none”) and the battery voltage is UVLO ≦ When Vbat <Va, state A2 outputs a LOW SHTDWN signal and a HIGH MODE signal to the modulation control unit 4a so that the bidirectional DC-DC converter 4 performs a boost operation (power from the secondary battery 10 to the load). (Operation for boosting the battery voltage during supply). Then, the control unit 12 outputs a HIGH SWCNT signal to the electric circuit switching unit 11 to control the low loss regulator 111 to be turned on and the field effect transistor 112 to be turned off.

  Further, according to the configuration of the control unit 12 shown in FIG. 3, the control unit 12 is supplied with power from an external power source (external power source is “present”) and the battery voltage is UVLO ≦ When the state A3 of Vbat <Va is established, a LOW SHTDWN signal and a LOW MODE signal are output to the modulation control unit 4a, and the bidirectional DC-DC converter 4 performs a step-down operation (voltage is charged when the secondary battery 10 is charged). Is controlled to step down). The step-down operation is an operation for stepping down the voltage of the external power supply so as to be a predetermined voltage appropriate for charging or a predetermined voltage appropriate for the operation of the load device. Then, the control unit 12 outputs a HIGH SWCNT signal to the electric circuit switching unit 11 to control the low loss regulator 111 to be turned on and the field effect transistor 112 to be turned off. Further, according to the configuration of the control unit 12 shown in FIG. 3, the control unit 12 is supplied with power from an external power source (external power source is “present”) and the battery voltage is Vbat ≧≧, as shown in FIG. 4. In the Va state A4, a LOW SHTDWN signal and a LOW MODE signal are output to the modulation control unit 4a, and the bidirectional DC-DC converter 4 performs a step-down operation (steps down the voltage when the secondary battery 10 is charged). To control). The step-down operation is also an operation for stepping down the voltage of the external power supply so as to be a predetermined voltage appropriate for charging or a predetermined voltage appropriate for the operation of the load device. Then, the control unit 12 outputs a LOW SWCNT signal to the electric circuit switching unit 11 to control the low loss regulator 111 to be turned off and the field effect transistor 112 to be turned on.

  Further, according to the configuration of the control unit 12 shown in FIG. 3, the control unit 12 does not supply power from the external power source (the external power source is “no”) and the battery voltage is Vbat <UVLO as shown in FIG. In the state A5, the HIGH SHTDWN signal is output to the modulation control unit 4a to control the operation of the bidirectional DC-DC converter 4 to OFF. Then, the control unit 12 outputs a HIGH SWCNT signal to the electric circuit switching unit 11 to control the low loss regulator 111 to be turned on and the field effect transistor 112 to be turned off.

  FIG. 5 shows a relationship in which the state of the power supply device transitions to each of the states A1 to A5. FIG. 6 is a timing chart until the state of the power supply device changes from the state A1 to the state A5 through the state A2. FIG. 7 is a timing chart until the state of the power supply device changes from the state A2 to the state A4 through the state A3. FIG. 8 shows a power supply path in the state A1. FIG. 9 shows a power supply path in the state A2. FIG. 10 shows a power supply path in the state A3. FIG. 11 shows a power supply path in the state A4. FIG. 12 shows a power supply path in the state A5.

  First, the case of the state A1 where Vbat ≧ Va and no external power supply is connected to the external power supply terminal 1 will be described with reference to FIGS. State A1 is shown as an initial state in FIG. 6 and corresponds to a range from time t0 to time t1. When the control state of the power supply device is in the state A1, the external voltage detection circuit 121 of the control unit 12 outputs a LOW signal. On the other hand, the battery low voltage detection circuit 122 and the UVLO voltage detection circuit 123 both output a HIGH signal. In that case, since both of the input signals are HIGH, the logic circuit 124 outputs a HIGH signal. Further, since the input signal received from the external voltage detection circuit 121 is LOW and the input signal received from the logic circuit 124 is HIGH, the logic circuit 126 outputs a HIGH SHTDWN signal to the modulation control unit 4a. Note that the operation switching circuit 47 of the modulation control unit 4a stops the operation of the bidirectional DC-DC converter 4 when receiving the HIGH SHTDWN signal. In short, the control unit 12 whose control state is in the state A1 outputs LOW to the MODE signal and HIGH to the SHTDWN signal.

  At this time, the logic circuit 127 outputs a LOW signal obtained by inverting the logic level of the HIGH input signal. Then, the delay circuit 128 delays the signal output from the logic circuit 127 from time t1 to t2 (FIG. 6), and outputs the delayed signal to the electric circuit switching unit 11 as the SWCNT signal. Upon receiving the LOW SWCNT signal, the electric circuit switching unit 11 turns off the function of the low-loss regulator 111 and turns on the field effect transistor 112.

  In this way, when Vbat ≧ Va, in the state A1 in which no external power supply is connected to the external power supply terminal 1, the power supply device does not boost the output voltage of the secondary battery 10 and the secondary battery 10 Is supplied to the load via the field effect transistor 112 of the circuit switching unit 11.

  Next, the case of the state A2 where UVLO ≦ Vbat <Va and no external power supply is connected to the external power supply terminal 1 will be described with reference to FIGS. The state A2 corresponds to the range from time t1 to t3 in FIG. At time t1, when the battery voltage Vbat decreases and the control state of the power supply device transitions from the state A1 to the state A2, the external voltage detection circuit 121 and the battery low voltage detection circuit 122 of the control unit 12 output a LOW signal. Output. On the other hand, the UVLO voltage detection circuit 123 outputs a HIGH signal. In that case, the logic circuit 124 outputs a LOW signal because only one of the input signals is HIGH. Further, since both of the input signals are LOW, the logic circuit 126 outputs a LOW SHTDWN signal to the modulation control unit 4a. The operation switching circuit 47 of the modulation control unit 4a operates the bidirectional DC-DC converter 4 when receiving the LOW SHTDWN signal.

  On the other hand, since both of the input signals are LOW, the logic circuit 125 outputs a HIGH MODE signal to the modulation control unit 4a. When receiving the HIGH MODE signal, the operation switching circuit 47 of the modulation control unit 4a switches the input signal of the switch 48 to the error amplifier 46 side.

  At this time, the logic circuit 127 outputs a HIGH signal obtained by inverting the logic level of the LOW input signal. Then, the delay circuit 128 slightly delays the signal output from the logic circuit 127 and outputs the delayed signal to the electric circuit switching unit 11 as the SWCNT signal. When receiving the HIGH SWCNT signal, the electric circuit switching unit 11 turns on the low-loss regulator 111 and turns off the field effect transistor 112.

  When the bidirectional DC-DC converter 4 starts to operate, the field effect transistors 5 and 6 are switched by the pulse wave output from the pulse width modulation circuit 42. Here, the pulse waves output to the field effect transistors 5 and 6 are in antiphase. Therefore, the switches 5 and 6 are switched so as to open and close alternately. In this way, the bidirectional DC-DC converter 4 boosts the output voltage of the secondary battery 10.

  Here, the error amplifier 46 detects an error in the voltage value of the output boosted by the bidirectional DC-DC converter 4 with respect to the voltage value Vref2 to be supplied to the load. For example, when the voltage value of the output boosted by the bidirectional DC-DC converter 4 is smaller than Vref2, the error amplifier 46 outputs a signal having a potential lower than the reference output potential to the pulse width modulation circuit 42. . On the other hand, when the output voltage value boosted by the bidirectional DC-DC converter 4 is larger than Vref2, the error amplifier 46 outputs a signal having a potential higher than the reference output potential to the pulse width modulation circuit 42.

  When the pulse width modulation circuit 42 receives a signal having a potential lower than the reference output potential from the error amplifier 46, the pulse width modulation circuit 42 makes the time for which the field effect transistor 5 is turned on longer and makes the time for turning it off shorter. On the contrary, the pulse width of the pulse wave is modulated and outputted so that the time during which the field effect transistor 6 is turned off is made longer and the time when the field effect transistor 6 is turned on is made shorter. On the other hand, when the pulse width modulation circuit 42 receives a signal having a potential higher than the reference output potential from the error amplifier 46, the time when the field effect transistor 5 is turned on is shortened and the time when it is turned off is lengthened. On the contrary, the pulse width of the pulse wave is modulated and output so that the time during which the field effect transistor 6 is turned off is shortened and the time during which the field effect transistor 6 is turned on is lengthened.

  In this way, when UVLO ≦ Vbat <Va and the external power source 1 is not connected to the external power source A 2, the power source device boosts the output of the secondary battery 10 with the bidirectional DC-DC converter 4. Then, power is supplied to the load via the low-loss regulator 111 of the electric circuit switching unit 11.

  Next, the case of the state A3 where UVLO ≦ Vbat <Va and the external power supply 1 is connected to the external power supply terminal 1 will be described with reference to FIGS. At this time, the battery low voltage detection circuit 122 of the control unit 12 outputs a LOW signal. On the other hand, the external voltage detection circuit 121 and the UVLO voltage detection circuit 123 output a HIGH signal. In that case, since the input signal received from the external voltage detection circuit 121 is HIGH, the logic circuit 126 outputs a LOW SHTDWN signal to the modulation control unit 4a. The operation switching circuit 47 of the modulation control unit 4a operates the bidirectional DC-DC converter 4 when receiving the LOW SHTDWN signal.

  At this time, since one input signal is HIGH, the logic circuit 125 outputs a LOW MODE signal to the modulation control unit 4a. When receiving the LOW MODE signal, the operation switching circuit 47 of the modulation control unit 4a switches the switch 48 to the charge control circuit 43 side.

  At this time, the logic circuit 127 outputs a HIGH signal obtained by inverting the logic level of the LOW input signal. Then, the delay circuit 128 slightly delays the signal output from the logic circuit 127 and outputs the delayed signal to the electric circuit switching unit 11 as the SWCNT signal. When receiving the HIGH SWCNT signal, the electric circuit switching unit 11 turns on the low-loss regulator 111 and turns off the field effect transistor 112.

  When the bidirectional DC-DC converter 4 starts to operate, the field effect transistors 5 and 6 are switched by the pulse wave output from the pulse width modulation circuit 42. Here, the pulse waves output to the field effect transistors 5 and 6 are in antiphase. Therefore, the switches 5 and 6 are switched so as to open and close alternately. At this time, since the potential on the external power supply terminal 1 side of the inductor 7 is higher than the potential on the opposite side, the current output from the external power supply flows to the inductor 7. In this way, the bidirectional DC-DC converter 4 steps down the output of the external power supply and outputs it.

  In this way, when UVLO ≦ Vbat <Va, in the state A3 in which the external power supply is connected to the external power supply terminal 1, the power supply apparatus steps down the output of the external power supply by the bidirectional DC-DC converter 4. And supplied to the secondary battery 10. In this way, the secondary battery 10 is charged. Further, the power supply device also supplies the output of the external power supply to the load via the low loss regulator 111 of the electric circuit switching unit 11.

  At this time, the error amplifier 44 detects an error in the value of the current flowing through the resistor 9 with respect to the reference current value Iref when the secondary battery 10 is charged with a constant current. For example, when the current value flowing through the resistor 9 is larger than the reference current value Iref when the secondary battery 10 is charged with constant current, the error amplifier 44 outputs a signal having a potential lower than the reference output potential. Output to the charge control circuit 43. On the other hand, when the value of the current flowing through the resistor 9 is smaller than the reference current value Iref when the secondary battery 10 is charged with constant current, the error amplifier 44 performs charge control on a signal having a potential higher than the reference output potential. Output to the circuit 43.

  The error amplifier 45 detects an error in the battery voltage Vbat of the secondary battery 10 with respect to the reference voltage value Vref1 when the secondary battery 10 is charged at a constant voltage. For example, when the battery voltage Vbat of the secondary battery is smaller than the reference voltage value Vref1 when the secondary battery 10 is charged at a constant voltage, the error amplifier 45 outputs a signal having a potential lower than the reference output potential. Output to the charge control circuit 43. On the other hand, when the battery voltage Vbat of the secondary battery is larger than the reference voltage value Vref1 when the secondary battery 10 is charged at a constant voltage, the error amplifier 45 performs charge control on a signal having a potential higher than the reference output potential. Output to the circuit 43.

  The secondary battery 10 is charged first by constant current control and then by constant voltage control. For example, the charging control circuit 43 outputs a signal output from the error amplifier 44 to the pulse width modulation circuit 44 immediately after the charging of the secondary battery 10 is started. For example, when it is determined that a signal having a higher potential than the reference output potential is continuously output from the error amplifier 44 for a predetermined time or longer, the charge control circuit 43 outputs a signal output from the error amplifier 45. Is output to the pulse width modulation circuit 44.

  When the pulse width modulation circuit 42 receives a signal having a potential lower than the reference output potential from the charging control circuit 43, the pulse width modulation circuit 42 shortens the time during which the field effect transistor 5 is turned on, and lengthens the time during which the field effect transistor 5 is turned off. On the contrary, the pulse width of the pulse wave is modulated and outputted so that the time during which the field effect transistor 6 is turned off is longer and the time during which the field effect transistor 6 is turned on is shorter. On the other hand, when the pulse width modulation circuit 42 receives a signal having a potential higher than the reference output potential from the charging control circuit 43, the time during which the field effect transistor 5 is turned on is lengthened and the time during which the field effect transistor 5 is turned off is shortened. On the contrary, the pulse width of the pulse wave is modulated and output so that the time when the field effect transistor 6 is turned off is shortened and the time when the field effect transistor 6 is turned on is lengthened.

  In this way, when UVLO ≦ Vbat <Va, in the state A3 in which the external power supply is connected to the external power supply terminal 1, the power supply apparatus steps down the output of the external power supply by the bidirectional DC-DC converter 4. Thus, when charging the secondary battery 10, constant current charging is performed at the reference current value Iref. When the secondary battery 10 cannot be charged with the constant current with the reference current value Iref, the power supply device charges the secondary battery 10 with the reference voltage value Vref1 at a constant voltage.

  Next, the case of the state A4 where Vbat ≧ Va and an external power supply is connected to the external power supply terminal 1 will be described with reference to FIGS. At this time, the external voltage detection circuit 121, the battery low voltage detection circuit 122, and the UVLO voltage detection circuit 123 of the control unit 12 output a HIGH signal. In that case, since the input signal received from the external voltage detection circuit 121 is HIGH, the logic circuit 126 outputs a LOW SHTDWN signal to the modulation control unit 4a. The operation switching circuit 47 of the modulation control unit 4a operates the bidirectional DC-DC converter 4 when receiving the LOW SHTDWN signal.

  At this time, since both input signals are HIGH, the logic circuit 125 outputs a LOW MODE signal to the modulation control unit 4a. When receiving the LOW MODE signal, the operation switching circuit 47 of the modulation control unit 4a switches the switch 48 to the charge control circuit 43 side.

  At this time, the logic circuit 127 outputs a LOW signal obtained by inverting the logic level of the HIGH input signal. Then, the delay circuit 128 slightly delays the signal output from the logic circuit 127 and outputs the delayed signal to the electric circuit switching unit 11 as the SWCNT signal. Upon receiving the LOW SWCNT signal, the electric circuit switching unit 11 turns off the low-loss regulator 111 and turns on the field effect transistor 112.

  When the bidirectional DC-DC converter 4 starts to operate, the field effect transistors 5 and 6 are switched by the pulse wave output from the pulse width modulation circuit 42. Here, the pulse waves output to the field effect transistors 5 and 6 are in antiphase. Therefore, the switches 5 and 6 are switched so as to open and close alternately. At this time, since the potential on the external power supply terminal 1 side of the inductor 7 is higher than the potential on the opposite side, the current output from the external power supply flows to the inductor 7. In this way, the bidirectional DC-DC converter 4 steps down the output of the external power supply and outputs it.

  In this way, when Vbat ≧ Va, in the state A4 where the external power supply is connected to the external power supply terminal 1, the power supply apparatus steps down the output of the external power supply by the bidirectional DC-DC converter 4, While supplying to the secondary battery 10, it supplies also to load via the field effect transistor 112 of the electric circuit switching part 11. FIG.

  At this time, the error amplifier 44 detects an error in the value of the current flowing through the resistor 9 with respect to the reference current value Iref when the secondary battery 10 is charged with a constant current. For example, when the current value flowing through the resistor 9 is larger than the reference current value Iref when the secondary battery 10 is charged with constant current, the error amplifier 44 outputs a signal having a potential lower than the reference output potential. Output to the charge control circuit 43. On the other hand, when the value of the current flowing through the resistor 9 is smaller than the reference current value Iref when the secondary battery 10 is charged with constant current, the error amplifier 44 performs charge control on a signal having a potential higher than the reference output potential. Output to the circuit 43.

  Further, the error amplifier 45 detects an error of the battery voltage Vbat of the secondary battery with respect to the reference voltage value Vref1 when the secondary battery 10 is charged at a constant voltage. For example, when the battery voltage Vbat of the secondary battery is smaller than the reference voltage value Vref1 when the secondary battery 10 is charged at a constant voltage, the error amplifier 45 outputs a signal having a potential lower than the reference output potential. Output to the charge control circuit 43. On the other hand, when the battery voltage Vbat of the secondary battery is larger than the reference voltage value Vref1 when the secondary battery 10 is charged at a constant voltage, the error amplifier 45 performs charge control on a signal having a potential higher than the reference output potential. Output to the circuit 43.

  The charging control circuit 43 outputs a signal output from the error amplifier 44 immediately after the secondary battery 10 starts to be charged. For example, when a signal having a potential higher than the reference output potential is continuously output from the error amplifier 44 for a predetermined time or more, the charge control circuit 43 outputs a signal output from the error amplifier 45.

  When the pulse width modulation circuit 42 receives a signal having a potential lower than the reference output potential from the charging control circuit 43, the pulse width modulation circuit 42 shortens the time during which the field effect transistor 5 is turned on, and lengthens the time during which the field effect transistor 5 is turned off. On the contrary, the pulse width of the pulse wave is modulated and outputted so that the time during which the field effect transistor 6 is turned off is longer and the time during which the field effect transistor 6 is turned on is shorter. On the other hand, when the pulse width modulation circuit 42 receives a signal having a potential higher than the reference output potential from the charging control circuit 43, the time during which the field effect transistor 5 is turned on is lengthened and the time during which the field effect transistor 5 is turned off is shortened. On the contrary, the pulse width of the pulse wave is modulated and output so that the time when the field effect transistor 6 is turned off is shortened and the time when the field effect transistor 6 is turned on is lengthened.

  In this way, when Vbat ≧ Va, in the state A4 where the external power supply is connected to the external power supply terminal 1, the power supply apparatus steps down the output of the external power supply by the bidirectional DC-DC converter 4, When charging the secondary battery 10, constant current charging is performed with the reference current value Iref. When the secondary battery 10 cannot be charged with the constant current with the reference current value Iref, the power supply device charges the secondary battery 10 with the reference voltage value Vref1 at a constant voltage.

  Next, the case of the state A5 where Vbat <UVLO and no external power supply is connected to the external power supply terminal 1 will be described with reference to FIGS. State A5 is shown as a state after time t3 in FIG. As shown in FIG. 6, since the power charged in the secondary battery 10 during the period of the state A2 is consumed, Vbat further decreases, and the control state of the power supply device transitions to the state A5. At this time, the external voltage detection circuit 121, the battery low voltage detection circuit 122, and the UVLO voltage detection circuit 123 of the control unit 12 output a LOW signal. In that case, the logic circuit 124 outputs a HIGH signal to the logic circuit 126 because both of the input signals are LOW. Further, since the input signal received from the external voltage detection circuit 121 is LOW and the input signal received from the logic circuit 124 is HIGH, the logic circuit 126 outputs a HIGH SHTDWN signal to the modulation control unit 4a. The operation switching circuit 47 of the modulation control unit 4a stops the operation of the bidirectional DC-DC converter 4 when receiving the HIGH SHTDWN signal.

  At this time, the logic circuit 127 outputs a HIGH signal obtained by inverting the logic level of the LOW input signal. Then, the delay circuit 128 slightly delays the signal output from the logic circuit 127 and outputs the delayed signal to the electric circuit switching unit 11 as the SWCNT signal. When receiving the HIGH SWCNT signal, the electric circuit switching unit 11 turns on the low-loss regulator 111 and turns off the field effect transistor 112.

  In this way, when Vbat <UVLO, in the state A5 where no external power supply is connected to the external power supply terminal 1, the power supply device stops (cuts off) the supply of power to the load.

  As described above, the power supply device according to the present embodiment can not only charge the secondary battery by reducing the power supplied from the external power source by the one bidirectional DC-DC converter 4, but also When the output voltage of the secondary battery falls below the required voltage, the output voltage of the secondary battery can be boosted and supplied to the load. Therefore, the boost DC-DC converter and the step-down DC-DC converter are separately provided. There is no need to prepare, and the number of parts can be reduced as compared with a known power supply device.

  Further, as described above, when the secondary battery 10 is at a low voltage, the power supply device according to the present embodiment boosts the output of the secondary battery 10 by the bidirectional DC-DC converter 4 and supplies the boosted output to the load. The secondary battery 10 can be made long lasting.

Note that the above-described power supply device may operate as follows.
For example, when the external power supply is connected to the external power supply terminal 1 and the battery voltage of the secondary battery 10 is the value at the time of full charge, the control unit 12 of the power supply device turns the bidirectional DC-DC converter 4 on. The electric circuit switching unit 11 may be operated so as to connect the input terminal TB11b to the output terminal TB11c, and the electric power of the external power supply may be stepped down and supplied to the load.

  Further, for example, when the external power supply is connected to the external power supply terminal 1, the control unit 12 of the power supply device is a bidirectional DC-DC converter when the battery voltage of the secondary battery 10 is a full charge value. 4 may be stopped, and the electric circuit switching unit 11 may be operated to connect the input terminal TB11a to the output terminal TB11c to supply the power of the external power source to the load.

  Further, for example, when the external power supply is connected to the external power supply terminal 1, the control unit 12 of the power supply device is a bidirectional DC-DC converter when the battery voltage of the secondary battery 10 is a full charge value. 4 may be stopped, and the electric circuit switching unit 11 may be operated to connect the input terminal TB11b to the output terminal TB11c to supply the power of the secondary battery 10 to the load.

  The power supply apparatus described above has a computer system inside. Each control process described above is stored in a computer-readable recording medium in the form of a program, and the above processing is performed by the computer reading and executing the program. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

  (Supplementary note 1) A bidirectional DC-DC converter that boosts and outputs the power of the secondary battery or steps down the power of the external power supply, and the boost output terminal of the bidirectional DC-DC converter and the external power supply A second input terminal connected to the step-down output terminal of the bidirectional DC-DC converter, the secondary battery, and an output terminal connected to the load. An electric circuit switching unit that connects one of the first input terminal and the second input terminal to the output terminal and switches a power supply path to the load; A control unit that controls the DC-DC converter and the electric circuit switching unit, and the control unit operates the bidirectional DC-DC converter when the external power source is not connected, and Connect the input end to the output end The electric circuit switching unit is operated to boost the power of the secondary battery and supply it to the load, or the operation of the bidirectional DC-DC converter is stopped, and the second input terminal is connected to the output terminal. Operating the electric path switching unit to connect to the load, supplying the power of the secondary battery to the load, and when the external power source is connected, operating the bidirectional DC-DC converter, A power supply apparatus, wherein the power of an external power supply is stepped down and supplied to the secondary battery.

  (Supplementary Note 2) When the battery voltage of the secondary battery is equal to or higher than a predetermined value when the external power source is not connected, the control unit stops the operation of the bidirectional DC-DC converter, and The power supply apparatus according to appendix 1, wherein the electric circuit switching unit is operated so as to connect two input terminals to the output terminal, and power of the secondary battery is supplied to the load.

  (Supplementary Note 3) When the battery voltage of the secondary battery is less than the predetermined value when the external power source is not connected, the control unit operates the bidirectional DC-DC converter and the first The power supply apparatus according to claim 1, wherein the electric circuit switching unit is operated so as to connect the input terminal of the secondary battery to the output terminal, and the power of the secondary battery is boosted and supplied to the load.

  (Additional remark 4) When the said external power supply is connected, the said control part operates the said bidirectional | two-way DC-DC converter, when the battery voltage of the said secondary battery is not the value at the time of a full charge, The electric circuit switching unit is operated so as to connect the first input terminal to the output terminal, and the power of the external power supply is stepped down and supplied to the secondary battery, and the power of the external power supply is supplied to the load. The power supply device according to any one of appendices 1 to 3, wherein the power supply device is supplied.

  (Supplementary Note 5) When the external power supply is connected, the control unit operates the bidirectional DC-DC converter when the battery voltage of the secondary battery is not a value at full charge, and From the appendix 1, wherein the electric circuit switching unit is operated so as to connect a second input terminal to the output terminal, and the electric power of the external power source is stepped down and supplied to the secondary battery and the load. 4. The power supply device according to any one of 3.

  (Supplementary Note 6) When the external power supply is connected, the control unit operates the bidirectional DC-DC converter when the battery voltage of the secondary battery is a value at full charge, and Any one of appendices 1 to 5, wherein the electric circuit switching unit is operated so as to connect the second input terminal to the output terminal, and the electric power of the external power source is stepped down and supplied to the load. The power supply device according to item.

  (Additional remark 7) The said control part is a case where the said external power supply is connected, and when the battery voltage of the said secondary battery is a value at the time of a full charge, it stops operation | movement of the said bidirectional | two-way DC-DC converter And operating the electric circuit switching unit to connect the first input terminal or the second input terminal to the output terminal, and supplying the power of the external power source or the secondary battery to the load. The power supply device according to any one of appendices 1 to 5, characterized by:

  (Additional remark 8) The said control part is less than the minimum voltage value required in order for the battery voltage of the said secondary battery to operate | move normally when the said external power supply is not connected. When the operation of the bidirectional DC-DC converter is stopped, the electric circuit switching unit is operated so as to connect the first input terminal to the output terminal, and the supply of power to the load is stopped. The power supply device according to any one of appendices 1 to 7, characterized in that:

  (Additional remark 9) A portable terminal device provided with the power supply device as described in any one of Additional remark 1 to 8.

  (Supplementary Note 10) When the external power supply is not connected, the bidirectional DC-DC converter is operated, and the first input terminal connected to the boost output terminal of the bidirectional DC-DC converter and the external power supply is connected. The electric circuit switching unit is operated so as to be connected to the output terminal connected to the load, and the power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is stopped. The electric circuit switching unit is operated so that a second input terminal connected to the step-down output terminal of the bidirectional DC-DC converter and the secondary battery is connected to the output terminal; When power is supplied to the load and the external power supply is connected, the bidirectional DC-DC converter is operated to step down the power of the external power supply and supply it to the secondary battery. The method of the power supply device according to.

  (Supplementary Note 11) When the external power source is not connected to the computer, the bidirectional DC-DC converter is operated, and the first connected to the boost output terminal of the bidirectional DC-DC converter and the external power source The electric circuit switching unit is operated so as to connect the input terminal to the output terminal connected to the load, and the power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is performed. The electric circuit switching unit is operated so as to connect the second input terminal connected to the step-down output terminal of the bidirectional DC-DC converter and the secondary battery to the output terminal. When the power of the secondary battery is supplied to the load and the external power source is connected, the bidirectional DC-DC converter is operated to step down the power of the external power source and supplied to the secondary battery. Program for causing to function as control means for.

DESCRIPTION OF SYMBOLS 1 External power supply terminal 2 Diode 3 Bypass capacitor 4 Bidirectional DC-DC converter 4a Modulation control part 5 Field effect transistor 6 Field effect transistor 7 Inductor 8 Smoothing capacitor 9 Resistor 10 Secondary battery 11 Electric path switching part 12 Control part 42 Pulse width Modulation circuit 43 Charge control circuit 44 Comparator 45 Comparator 46 Comparator 47 Operation switching circuit 48 Switch 111 Low loss regulator 112 Field effect transistor 121 External voltage detection circuit 122 Battery low voltage detection circuit 123 UVLO voltage detection circuit 124 Logic circuit 125 Logic circuit 126 Logic Circuit 127 Logic circuit 128 Delay circuit

Claims (10)

A bidirectional DC-DC converter that boosts and outputs the power of the secondary battery, or steps down and outputs the power of the external power supply;
A first input terminal connected to the step-up output terminal of the bidirectional DC-DC converter and the external power source, a step-down output terminal of the bidirectional DC-DC converter, and a second terminal connected to the secondary battery. And an output end connected to a load, wherein either one of the first input end and the second input end is connected to the output end, and the load An electric circuit switching unit for switching an electric power supply path to
A control unit that controls the bidirectional DC-DC converter and the electric circuit switching unit;
The controller is
When the external power supply is not connected, the secondary battery is operated by operating the bidirectional DC-DC converter and operating the electric circuit switching unit to connect the first input terminal to the output terminal. The electric circuit switching unit is operated so that the second input terminal is connected to the output terminal and the operation of the bidirectional DC-DC converter is stopped. , Supplying power of the secondary battery to the load,
When the external power supply is connected, the bidirectional DC-DC converter is operated, and the power of the external power supply is stepped down and supplied to the secondary battery. The control unit is a case where the external power source is not connected, and when the battery voltage of the secondary battery is equal to or higher than a predetermined value, the operation of the bidirectional DC-DC converter is stopped and the second input terminal The power supply device according to claim 1, wherein the electric circuit switching unit is operated so as to be connected to the output terminal, and the electric power of the secondary battery is supplied to the load. The control unit is a case where the external power source is not connected. When the battery voltage of the secondary battery is less than the predetermined value, the control unit operates the bidirectional DC-DC converter and the first input terminal The power supply device according to claim 1, wherein the electric circuit switching unit is operated so as to be connected to the output terminal, and the power of the secondary battery is boosted and supplied to the load. The control unit is a case where the external power source is connected, and when the battery voltage of the secondary battery is not a value at full charge, the bidirectional DC-DC converter is operated and the first Operating the electric circuit switching unit to connect the input terminal to the output terminal, stepping down the power of the external power source and supplying the power to the secondary battery, and supplying the power of the external power source to the load. The power supply device according to any one of claims 1 to 3, wherein: The control unit is a case where the external power supply is connected, and when the battery voltage of the secondary battery is not a value at the time of full charge, the bidirectional DC-DC converter is operated and the second The electric circuit switching unit is operated so as to connect an input terminal to the output terminal, and the electric power of the external power source is stepped down and supplied to the secondary battery and the load. The power supply device according to any one of the above. The control unit is a case where the external power source is connected, and when the battery voltage of the secondary battery is a value at the time of full charge, the bidirectional DC-DC converter is operated, and the second The electric circuit switching unit is operated so that an input terminal is connected to the output terminal, and the electric power of the external power supply is stepped down and supplied to the load. The power supply described. The control unit is a case where the external power source is connected, and when the battery voltage of the secondary battery is a value at the time of full charge, the control unit stops the operation of the bidirectional DC-DC converter, and The electric circuit switching unit is operated so as to connect one input terminal or the second input terminal to the output terminal, and the electric power of the external power source or the secondary battery is supplied to the load. The power supply device according to any one of claims 1 to 5.   A portable terminal device provided with the power supply device as described in any one of Claims 1-7. When the external power supply is not connected, the bidirectional DC-DC converter is operated, and the boosted output terminal of the bidirectional DC-DC converter and the first input terminal connected to the external power supply are connected to the load. The electric circuit switching unit is operated so as to be connected to the output terminal, and the power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is stopped and the bidirectional The electric circuit switching unit is operated so that a second input terminal connected to the step-down output terminal of the DC-DC converter and the secondary battery is connected to the output terminal, and the electric power of the secondary battery is supplied to the load. To supply
When the external power supply is connected, the bidirectional DC-DC converter is operated, and the power of the external power supply is stepped down and supplied to the secondary battery. Computer
When the external power supply is not connected, the bidirectional DC-DC converter is operated, and the boosted output terminal of the bidirectional DC-DC converter and the first input terminal connected to the external power supply are connected to the load. The electric circuit switching unit is operated so as to be connected to the output terminal, and the power of the secondary battery is boosted and supplied to the load, or the operation of the bidirectional DC-DC converter is stopped and the bidirectional The electric circuit switching unit is operated so that a second input terminal connected to the step-down output terminal of the DC-DC converter and the secondary battery is connected to the output terminal, and the electric power of the secondary battery is supplied to the load. To supply
When the external power source is connected, the program functions as control means for operating the bidirectional DC-DC converter to step down the power of the external power source and supply it to the secondary battery.

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