JP2009189212A - Power supply device and output switching method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply device and an output switching method capable of efficiently switching voltage output.
A voltage converter 10 that converts an input voltage from a power supply 30 into a predetermined output voltage and a load state corresponding to the connection state by detecting a connection state of load devices at a plurality of output terminals 13 _{1 to} 13 _N a detection signal _P 1 to P _N connection status detecting unit ₁₄ 1 to 14 _N for generating, in response to receiving a load detection signal _P 1 to P _N generated by the connection state detection unit ₁₄ 1 to 14 _N, a predetermined and a plurality of output terminals 13 ₁ to 13 _N control unit 11 which the output voltage of the plurality of output terminals 13 ₁ to 13 _N terminal determines one output terminal which is supplied on the basis of the power feeding priorities were determined And switch units 12 _{1 to} 12 _N that selectively supply an output voltage to one output terminal.
[Selection] Figure 1

Description

  The present invention relates to a power supply apparatus having a plurality of output terminals and an output switching method.

Conventionally, as a technique in such a field, there is JP-A-5336653. This publication describes a power jack exclusive output automatic switching device including a plurality of output paths, a load device detection unit and an exclusive output switching unit arranged in each output path.
Japanese Patent Laid-Open No. 5-336653

  However, although the power jack exclusive output automatic switching device described in Patent Document 1 has a plurality of output paths, the output cable connected first is given priority, and the load device connected later is connected. It was difficult to switch the output destination.

  Therefore, the present invention has been made in view of such a problem, and an object thereof is to provide a power supply device and an output switching method capable of efficiently switching voltage output.

In order to solve the above-described problem, a power supply device according to the present invention detects a connection state of a voltage conversion unit that converts an input voltage from a power source into a predetermined output voltage, and a load device at a plurality of output terminals. A connection state detection unit that generates a load detection signal corresponding to the state, and a plurality of predetermined output terminals based on power supply priority orders in response to reception of the load detection signal generated by the connection state detection unit. A control unit that determines one output terminal to which an output voltage is supplied among the output terminals, and a first switching unit that selectively switches and supplies the output voltage to the determined one output terminal;
It is characterized by providing.

  In the power supply device according to the present invention, one output terminal to which an output voltage is supplied is determined based on a priority order relating to power feeding of a plurality of output terminals determined in advance by the control unit. That is, even an output terminal to which a load device is connected later can be supplied with a predetermined output voltage converted by the voltage conversion unit based on a predetermined power feeding priority. Therefore, according to the power supply device according to the present invention, it is possible to efficiently switch the power supply destination. In addition, when a power source is built in the power supply device according to the present invention, an output voltage is supplied to one determined output terminal, so even when a plurality of load devices are connected simultaneously, The source does not need to supply the maximum amount of total power required by each connected load device, thus preventing the power source from growing. As a result, the power supply device can be reduced in size, weight, and cost.

  Further, it is preferable that the control unit controls the voltage conversion unit so that the predetermined output voltage becomes a predetermined voltage value for one output terminal. Thereby, the kind of load apparatus connected to the output terminal for every output terminal can be matched on a one-to-one basis. As a result, the output characteristics of the output terminal can be matched with the input electrical characteristics of the load device connected to the output terminal.

  In addition, when it is determined that supply of an output voltage to one output terminal is based on a load detection signal from the connection state detection unit, a load device is connected to one or more output terminals among the plurality of output terminals. It is preferred to start. Thereby, it can prevent that electric power is consumed in a no-load state, and can reduce power consumption.

  Moreover, it further includes a second switching unit connected between the power source and the voltage conversion unit, and the second switching unit controls the switch switching state based on the switch and the load detection signal. It is preferable to have In this case, power consumption can be reduced by turning on and off the connection between the power source and the voltage conversion unit according to the connection state of the load.

  The switch control unit is a negative logic OR that turns on the switch when it is determined that the load device is connected to at least one of the plurality of output terminals based on the load detection signal for each of the plurality of output terminals. It is preferable to include a circuit. In this case, since the power source and the voltage conversion unit are connected when at least one load device is connected to the output terminal, it is possible to reduce power consumption in a no-load state.

  The control unit includes a priority output destination determination unit that determines an output terminal having a higher power supply priority order as one output terminal from among the output terminals from which connection of the load device is detected, and a control signal from the priority output destination determination unit Accordingly, it is preferable to include a logic negation unit that exclusively switches the output voltage to one output terminal. In this case, the output voltage can be exclusively output to one output terminal having a high priority.

  In the output switching method according to the present invention, the voltage conversion unit converts the input voltage from the power source into a predetermined output voltage, and the connection state detection unit is connected to the load device at a plurality of output terminals. A connection state detection step for generating a load detection signal corresponding to the connection state, and the control unit receives a plurality of predetermined output terminals in response to reception of the load detection signal generated by the connection state detection unit. A control step for determining one output terminal to which an output voltage is supplied among a plurality of output terminals based on the power supply priority order, and the first switching means selectively selects the output voltage for the determined one output terminal. And a switching step of switching to supply.

  In the output switching method according to the present invention, in the control step by the control unit, one output terminal to which an output voltage is supplied is determined based on a predetermined priority order regarding power feeding to a plurality of output terminals. In other words, even an output terminal to which a load device is connected later can be supplied with a predetermined output voltage converted by the voltage conversion unit based on a predetermined power supply priority order. Therefore, according to the output switching method according to the present invention, it is possible to efficiently switch the power supply destination. In addition, when a power source is incorporated in a power supply device using the output switching method according to the present invention, an output voltage is supplied to one output terminal determined in the switching step by switching, and thus a plurality of load devices Even when the power sources are connected at the same time, the power source does not need to supply the total power of the maximum power required by each connected load device, and therefore, the enlargement of the power source can be prevented. As a result, the power supply apparatus using the output switching method according to the present invention can be reduced in size, weight, and cost.

  According to the present invention, voltage output can be switched efficiently.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, embodiments that are considered to be the best in carrying out the invention will be described in detail with reference to the accompanying drawings. In addition, the same code | symbol is attached | subjected about the same or equivalent element, and the description is abbreviate | omitted when description overlaps.

(First embodiment)
FIG. 1 is a circuit block diagram of a power supply device 1A according to the first embodiment.

The power supply device 1A supplies a voltage to an output terminal determined based on a power supply priority order of a plurality of output terminals determined in advance among the plurality of output terminals. The second switching means (switch 21, switch Control unit 7), voltage conversion unit 10, control unit 11, switch unit (first switching means) 12 _{1 to} 12 _N , output terminals 13 _{1 to} 13 _N , and connection state detection units 14 _{1 to} 14 It is composed of _N.

  The power supply 30 is a power source of the power supply device 1A, and is configured by an AC adapter or a battery. Here, the power supply 30 may be incorporated in the power supply apparatus 1A as necessary.

  The switch 21 controls electrical connection or disconnection between the power supply 30 and the voltage conversion unit 10, and is a p-channel MOSFET, for example. The switch 21 has a source connected to the external power supply 30 and a drain connected to the voltage conversion unit 10 and the control unit 11. The gate is connected to a switch control unit 7 described later.

The switch control unit 7 determines that the load device is connected to at least one output terminal among the plurality of output terminals 13 _{1 to} 13 _N based on a load detection signal from connection state detection units 14 _{1 to} 14 _N described later. When this is done, the switch 21 is turned on, and includes diodes 23 ₁ to 23 _N and resistors 22 and 24 _{1 to} 24 _N. The anodes of the diodes 23 ₁ to 23 _N are connected to the gate of the switch 21 and are connected between the source of the switch 21 and the power supply 30 via the resistor 22. The cathodes of the diodes 23 ₁ to 23 _N are connected to the corresponding connection state detection units 14 _{1 to} 14 _N , and are connected to the power source 30 and the source of the switch 21 via the corresponding resistors 24 _{1 to} 24 _N. Connected between. A diode ₂₃ 1 ~ 23 _N, the load on the at least one output terminal of the plurality of output terminals ₁₃ 1 to 13 _N on the basis of the load detection signal _P 1 to P _N for a plurality of output terminals ₁₃ 1 to 13 _N A negative logic OR circuit is configured to turn on the switch 21 when it is determined that the device is connected.

The voltage conversion unit 10 converts the voltage from the power source 30 into a predetermined output voltage at a predetermined output terminal based on an instruction from the control unit 11 described later, and is a switching converter or a series regulator. The voltage conversion unit 10 has one end connected to the drain of the switch 21 and the other end connected to the output terminals 13 _{1 to} 13 _N via the switch units 12 _{1 to} 12 _N , respectively. Note that the switch units 12 _{1 to} 12 _N are made of MOSFETs. Each of the output terminals 13 _{1 to} 13 _N can be fitted with connectors 69 _{1 to} 69 _N having a shape connected to the power supply terminal of the load device.

Further, the output terminal ₁₃ 1 to 13 _N respectively, to detect the connection state of the load device at the respective output terminal, the connection state detection unit ₁₄ 1 to 14 for generating a load detection signal _P 1 to P _N the corresponding _N is connected. The load detection signals P _{1 to} P _N are set to the output voltage (signal _SH ) of the power supply 30 when the load device is not connected, and to the ground potential (signal S _L when the load device is connected. ). Connection status detecting unit ₁₄ 1 to 14 _N generates a load detection signal _P 1 to P _N, and outputs it to the control unit 11 which will be described below load detection signal _P 1 to P _N.

Control unit 11, the connection state detection unit 14 _first load detection received signals P ₁ to P _N from to 14 _N, the priority determination of the power supply output terminal, the output voltage identification, the supply of the output voltage to the voltage converter 10 instruction, and it performs control of the switching state of the switch section ₁₂ 1 to 12 _N by the switch control signal _Q 1 to Q _N output to the switch unit ₁₂ 1 to 12 _N, and a for example a logic circuit and the microcomputer. The control unit 11 is connected to the connection state detection units 14 _{1 to} 14 _N , the switch units 12 _{1 to} 12 _N, and the voltage conversion unit 10 between the drain of the switch 21 and the voltage conversion unit 10.

The switch units 12 _{1 to} 12 _N selectively supply the output voltage from the voltage conversion unit 10 to one output terminal determined by the control unit 11, and are, for example, MOSFETs. In the switch units 12 _{1 to} 12 _N , each of the sources is connected to the voltage conversion unit 10, and each of the drains is connected to the corresponding output terminals 13 _{1 to} 13 _N. In addition, each of the gates of the switch units 12 _{1 to} 12 _N is connected to the control unit 11. Supply of an output voltage to one output terminal by the switch units 12 _{1 to} 12 _N is performed by applying a load device to one or more output terminals among the plurality of output terminals based on a load detection signal from the connection state detection units 14 _{1 to} 14 _N. It is started when it is determined that is connected. In the present embodiment, the output terminal 13 ₁ is a terminal for connection with the portable telephone, the output terminal 13 ₂ is a terminal for connection to a device having a USB (Univeral Serial Bus) interface.

  Below, operation | movement of 1 A of power supply devices is demonstrated.

In a state where the power supply 30 is connected to the switch 21, first, it is detected by the connection state detection units 14 _{1 to} 14 _N whether or not the connectors 69 _{1 to} 69 _N of the load device are connected to the output terminals 13 _{1 to} 13 _N , and the connection state is detected. The load detection signals P _{1 to} P _N corresponding to are generated. Specifically, when the load device to either the output terminal ₁₃ 1 to 13 _N is not connected, the connection state detection unit ₁₄ 1 to 14 _N of the load detection signal _P 1 to P _N all as a signal _{S H} generate. In this state, due to the resistor 22 and the resistors 24 _{1 to} 24 _N , the potential difference between the gate and the source of the switch 21 is near 0 volts, and the switch 21 is in an off state. On the other hand, when the load device is connected to one of output terminals of the output terminal 13 ₁ to 13 _N, to generate a load detection signal from the output terminal to which the load device is connected as the signal S _L. For example, when the load device is connected to the output terminal 13 _2, signal S _L is generated from the connection state detection unit 14 ₂ is outputted to the control unit 11.

When the signal S _L is generated from the connection state detection unit 14 _2, the gate voltage of the switch 21 drops to the ground potential via the diode 23 _2, switch 21 is turned on. When the switch 21 is turned on, a voltage is supplied from the power supply 30 to the voltage conversion unit 10 and the control unit 11. At this stage, the switch control signals Q ₁ to Q are supplied from the control unit 11 to the switch units 12 _{1 to} 12 _N. Q _N is the switch unit ₁₂ 1 to 12 _N so not output is off, therefore, the output terminal ₁₃ 1 to 13 _N is the output voltage from the voltage converter 10 is not supplied.

Next, the control unit 11 receives the load detection signals P _{1 to} P _N generated by the connection state detection units 14 _{1 to} 14 _{N, and} supplies an output voltage based on a predetermined power supply priority order of the output terminals. Output terminal to be determined. That is, the control unit 11 receives the load detection signal P ₁ to P _N, the load device to specify an output terminal connected 13 ₁ to 13 _N by identifying the outputted load detection signal as the signal S _L . Then, one output terminal with the highest power supply priority order is specified from among the specified output terminals 13 _{1 to} 13 _N , and the output terminal is determined as an output terminal to which an output voltage is supplied.

Next, the controller 11, for example, an output voltage instruction signal when the output terminal 13 ₂ is determined as the output destination identified predetermined outputs voltage to the output terminal 13 _2, corresponding to the identified output voltage Output to the voltage converter 10. The voltage conversion unit 10 receives the output voltage instruction signal and converts the voltage from the power supply 30 into an output voltage corresponding to the output voltage instruction signal.

Next, the control unit 11 outputs a switch control signal _{Q 2} of the output terminals 13 ₂ to the switching unit 12 _2, accordingly, the switch section 12 ₂ is turned on, the load device is connected through the connector 69 ₂ supplying an output voltage to an output terminal 13 ₂ are. By repeatedly executing the above function regularly, the control unit 11 can quickly switch the output when a load with a higher priority is connected even when the load device is already in the power supply state. .

In the power supply device ₁ </ b> A according to the present embodiment, _one output terminal to which an output voltage is supplied is determined based on a priority order related to power feeding of the plurality of output terminals 13 _{1 to} 13 _N determined in advance by the control unit 11. That is, even an output terminal to which a load device is connected later can be supplied with a predetermined output voltage converted by the voltage conversion unit 10 based on a predetermined power supply priority order. Therefore, according to the power supply device of the present embodiment, it is possible to efficiently switch the power supply destination. Further, when the power supply 30 is built in the power supply device, the output voltage is supplied to one determined output terminal, so that the power supply 30 is connected even when a plurality of load devices are connected simultaneously. It is not necessary to supply the total power of the maximum power required by each load device, and hence the power supply 30 can be prevented from becoming enlarged. As a result, the power supply device 1A can be reduced in size, weight, and cost.

In addition, the control unit 11 controls the voltage conversion unit 10 so that the output voltage becomes a predetermined voltage value for one output terminal. Thereby, the kind of load apparatus connected to the output terminal for every output terminal can be matched on a one-to-one basis. As a result, it is possible to match the input electrical characteristics of the load device connected to the output characteristics of the output terminals ₁₃ 1 to 13 _N to the output terminal ₁₃ 1 to 13 _N.

Further, the supply of the output voltage to one output terminal is performed by connecting one or more outputs among the plurality of output terminals 13 _{1 to} 13 _N to the connection state detection units 14 _{1 to} 14 _{N based} on the load detection signals P _{1 to} P _N. Starts when it is determined that a load device is connected to the terminal. Thereby, it can prevent that electric power is consumed in a no-load state, and can reduce power consumption.

In addition, a second switching unit connected between the power supply 30 and the voltage conversion unit 10 is further provided. The second switching unit includes the switch 21 and the switch 21 based on the load detection signals P _{1 to} P _N. And a switch control unit 7 for controlling the switching state. Thereby, power consumption can be reduced by turning on and off the connection between the power supply 30 and the voltage conversion unit 10 according to the connection state of the load.

The switch controller 7 includes diodes 23 ₁ to 23 _N , and outputs at least one of the plurality of output terminals 13 _{1 to} 13 _N based on the load detection signals P _{1 to} P _N for each of the plurality of output terminals. A negative logic OR circuit that turns on the switch 21 when it is determined that a load device is connected to the terminal is included. Therefore, when at least one load device is connected to the output terminals 13 _{1 to} 13 _N , the power supply 30 and the voltage conversion unit 10 are connected, so that power consumption in a no-load state can be reduced. .
(Second Embodiment)

  FIG. 2 is a circuit block diagram of a power supply device 1B according to the second embodiment.

  The power supply device 1B has a simplified configuration with the number of output terminals set to 2 in the configuration of the power supply device 1A of the first embodiment. The difference from the power supply device 1A of the first embodiment is that the control unit 11 Is composed of a priority output destination determination unit 26 and a logic negation unit 27. Since the other configuration is the same as that of the power supply device 1A, the same reference numerals are given and redundant description is omitted.

The priority output destination determination unit 26 constitutes a part of the control unit 11 and receives the load detection signals P _{1 to} P ₂ among the functions of the control unit 11, identifies the output voltage, and outputs to the voltage conversion unit 10. A voltage supply instruction and switching control of the switch units 12 _{1 to} 12 ₂ are performed, and are configured by, for example, a logic circuit or a microcomputer. Priority output destination determination section 26 is intended to turn on only the operation, the switch section 12 ₁ of the output terminal of the power supply priority higher side when feeding priority is connected high side of the load device to the output terminal There, in the present embodiment is connected only to the connection state detection unit 14 ₁ has high powered priority output terminal 13 _1, corresponding to the output terminal 13 _1.

Further, the logic negation unit 27 includes the switch units 12 ₁ and 12 ₂ on the output terminal side that are determined to be connected to the load device based on the load detection signals P _{1 to} P ₂ generated from the connection state detection units 14 _{1 to} 14 _2. exclusively in the oN state as it is switched the other output terminal side to the oFF state, and is connected between the switch unit 12 ₁ and the switch section 12 _2. In the present embodiment, the output terminal 13 ₁ is a terminal for connection with the portable telephone, the output terminal 13 ₂ is a terminal for connection to a device having a USB (Univeral Serial Bus) interface.

  Below, operation | movement of the power supply device 1B is demonstrated.

In the state of being connected to the switch 21 of the power supply 30, first, it is detected whether or not the connectors 69 ₁ and 69 ₂ of the load device are connected to the output terminals 13 ₁ and 13 ₂ by the connection state detectors 14 ₁ and 14 ₂ . Load detection signals P ₁ and P ₂ corresponding to the connection state are generated. Specifically, when no load device is connected to any of the output terminals 13 ₁ and 13 ₂ , both of the load detection signals P ₁ and P ₂ from the connection state detection units 14 ₁ and 14 ₂ are signal S. _H is output, and the switch 21 is set to an off state.

On the other hand, when the load device to the output terminal ₁₃ 1, 13 ₂ are connected, the connection state detection unit ₁₄ 1, 14 ₂ of at least one of generating a load detection signal _P 1, _{P 2} as the signal _{S L.} Then, the output of the negative logic OR circuit constituted by the diodes 23 ₁ to 23 ₂ becomes the ground level, and the switch 21 is turned on. When the switch 21 is turned on, the voltage of the power supply 30 is supplied to the voltage conversion unit 10.

Next, the control unit 11 including the priority output destination determination unit 26 and the logic negation unit 27 receives the load detection signals P ₁ and P ₂ generated by the connection state detection units 14 ₁ and 14 _{2 and} outputs a predetermined output. The output terminal to which the output voltage is supplied is determined based on the power supply priority order of the terminals. That is, when the load device is connected to the output terminal 13 _2, priority output destination determination section 26 does not operate and the output terminal 13 ₂ as an output terminal to which the output voltage is supplied by the logic negation unit 27 is determined, switch section 12 ₂ is turned on. On the other hand, when the load device to the output terminal 13 ₁ is connected, operates priority output destination determination section 26, 13 as an output terminal where the output voltage is supplied by the priority destination determining unit 26 ₁ is determined, the switch section 12 ₁ is turned on. At this time, the switch section 12 ₂ immediately before is in the ON state, the switch unit 12 ₁ is exclusively turned on by the logic negation unit 27, the switch section 12 ₂ is turned off.

Simultaneously with the determination of such an output terminal, the control unit 11 identifies a predetermined output voltage for the determined output terminal. Specifically, when the load device is connected to the output terminal 13 ₁ is preferentially output destination decision unit 26 is operating, the priority destination determining unit 26, a predetermined output voltage to the output terminal 13 ₁ Is output to the voltage conversion unit 10.

On the other hand, the voltage conversion unit 10 converts the voltage from the power source 30 into an output voltage corresponding to the output terminal determined by the control unit 11. Specifically, if 13 ₂ as an output terminal of the output voltage is supplied is determined, the output voltage priority output destination determination section 26 corresponds to the output terminal 13 ₂ by the voltage converter 10 without operation Generated. On the other hand, if the 13 ₁ as an output terminal to which the output voltage is supplied by the priority destination determining unit 26 is determined by the voltage converter 10, the output voltage corresponding to the output terminal 13 ₁ is generated.

Next, the switch units 12 ₁ and 12 ₂ selectively switch to the determined output terminal to supply the output voltage. Specifically, when the determined output terminal is an output terminal 13 _2, a predetermined output voltage to an output terminal 13 ₂ by the switch section 12 ₂ is supplied as a default. Further, when the determined output terminal is an output terminal 13 _1, the output voltage converted by the voltage converter 10 is supplied by the switch unit 12 _1.

In the power supply device 1 </ _b > B according to the present embodiment, the control unit 11 selects _one output terminal 13 ₁ , 13 ₂ having a higher power supply priority order from the output terminals 13 ₁ , 13 _{2 from} which connection of the load device is detected. A priority output destination determination unit 26 that is determined as an output terminal and a logic negation unit 27 that exclusively switches the output voltage to one output terminal according to a control signal from the priority output destination determination unit 26 are included. Thereby, an output voltage can be exclusively output to one output terminal with high priority.

Further, the priority destination determining unit 26, an output terminal 13 detects the connection state of _one of the load device, its only connection status detecting section 14 ₁ to generate a load detection signal P ₁ corresponding to the connection state is connected to cage, the connection state detection unit 14 ₂ is not connected. For this reason, the load detection signals P ₁ and P ₂ are not interfered with each other, so that the waiting time from when the load device is connected to when power feeding is started can be shortened.
(Third embodiment)

  FIG. 3 is a diagram showing the configuration of the power supply device 1C according to the third embodiment, and shows a more specific example of the configuration of the power supply device according to the second embodiment described above. When the configuration of the power supply device 1C is the same as that of the power supply device 1A, the same reference numerals are given and redundant description is omitted.

The voltage conversion unit 10 includes resistors 53, 54, and 55 connected in series with the booster 80 and the booster circuit controller 81. The step-up unit 80 includes capacitors 80 ₁ and 80 ₂ , an n-channel MOSFET 80 ₃ , a diode 80 _4, and a coil 80 ₅ . The other ends of the capacitor 80 ₁ and the capacitor 80 _2, each of the one end is grounded is connected to each other via a coil 80 ₅ and the diode 80 _4. Further, n-channel MOSFET 80 ₃ which source is grounded, its drain anode coil 80 ₅ and the diode 80 ₄ - is connected between the de.

One end of the other end coil 80 _fifth capacitor 80 ₁ of which one end is grounded is connected to the drain of the p-channel MOSFET21 in parallel. The other end of the coil 80 ₅ drains of the anode and the n-channel MOSFET 80 ₃ diodes 80 ₄ are connected in parallel. Also the cathode of the diode 80 ₄ is connected to an end of the other end of the capacitor 80 ₂ whose one end is grounded resistor 53.

Boosting circuit control section 81 includes a comparator 81 _1, the triangular wave generator 81 _2, and an error amplifier 81 _3. The error amplifier 81 _3, the reference voltage V _ref are input, one end of the other end with the resistor 54 of the resistor 53 to the noninverting input terminal is connected to its inverting input terminal. Note that the other end of the resistor 55 is connected to the other end of the resistor 54 whose one end is grounded. An output terminal of the error amplifier 81 ₃ has a non-inverting input a triangular wave generator 81 ₂ to the terminal is connected to the inverting input terminal of the comparator 81 ₁ is connected. The output terminal of the comparator 81 ₁ is connected to the gate of n-channel MOSFET 80 ₃ of the boosting unit 80.

  The voltage converter 10 including the booster 80, the booster circuit controller 81, and the resistors 53, 54, and 55 sets the output voltage according to the control of the controller 11.

  The priority output destination determination unit 26 of the control unit 11 includes n-channel MOSFETs 59 and 62, a p-channel MOSFET 63, and resistors 60 and 61.

  In the n-channel MOSFET 59, one end and the other end of the resistor 55 are connected to the source and the drain, respectively, and the gate is connected to the gate of the n-channel MOSFET 62 in which the source is grounded and the drain is connected to one end of the resistor 60. Has been. Between the gate of the n-channel MOSFET 59 and the gate of the n-channel MOSFET 62, the other end of the resistor 61 whose one end is grounded and the drain of the p-channel MOSFET 63 are connected in parallel. A resistor 64 of a logic negation unit 27 described later is connected between the source and gate of the p-channel MOSFET 63.

  The logic negation unit 27 of the control unit 11 includes resistors 64 and 75 and an n-channel MOSFET 68. The source of the n-channel MOSFET 68 is grounded, the gate is connected to the drain of the switch 21 via the resistor 64 connected to the source and gate of the p-channel MOSFET 63, and the drain is connected to one end of the resistor 75. It is connected.

Switch unit 12 _1, and a capacitor 56 and a resistor are connected in parallel to the capacitor 56 57 and p-channel MOSFET58 Prefecture. One end of the capacitor 56 and the resistor 57 is connected to the source of the p-channel MOSFET 58, and the other end of the capacitor 56 and the resistor 57 is connected to the other end of the resistor 60 and the gate of the p-channel MOSFET 58. The drain of p-channel MOSFET58 are connected to the connector 69 ₁ through the output terminal 13 _1.

Switch section 12 ₂ is composed of a capacitor 66 and a resistor are connected in parallel to the capacitor 66 65 and p-channel MOSFET67 Prefecture. One end of the capacitor 66 and the resistor 65 is connected to the source of the p-channel MOSFET 67, and the other end of the capacitor 66 and the resistor 65 is connected to the other end of the resistor 75 and the gate of the p-channel MOSFET 67. The drain of p-channel MOSFET67 are connected to the connector 69 ₂ via the output terminal 13 _2.

The power supply terminal of the load device 70 ₁ which is connected to the connector 69 _1, in addition to the power supply positive electrode and the negative electrode has a terminal for the negative terminal and internal shorted load detection, the load device connected to connector 69 ₂ 70 _In addition to the positive electrode and the negative electrode, the power supply terminal 2 has two data terminals, a negative electrode, and a frame ground that is internally short-circuited. In the present embodiment, the load device 70 ₁ is a portable telephone, the load device 70 ₂ is a device having a USB (Univeral Serial Bus) interface.

  Next, the operation of the power supply device 1C will be described in detail.

In the state of being connected to the switch 21 of the power supply 30, first, it is detected whether or not the connectors 69 ₁ and 69 ₂ of the load device are connected to the output terminals 13 ₁ and 13 ₂ by the connection state detectors 14 ₁ and 14 ₂ . Connection state detection units 14 ₁ and 14 ₂ corresponding to the connection state are generated. Specifically, when no load device is connected to any of the output terminals 13 ₁ and 13 ₂ , both of the load detection signals P ₁ and P ₂ from the connection state detection units 14 ₁ and 14 ₂ are signal S. _H is output, and the switch 21 is set to an off state.

If the power terminal of the load device 70 ₂ is connected only to the connector 69 _{and second} output terminals 13 _2, the connection state detection unit 14 ₂ generates a load detection signal _{P 2} as the signal _{S L,} thereby diodes ₂₃ 1 ~ the output of the negative logic OR circuit formed by 23 ₂ becomes the ground level, p-channel MOSFET21 through the diode 23 ₂ is turned on.

When the switch 21 is turned on, a voltage is supplied from the power supply 30 to the voltage conversion unit 10. Next, the control unit 11 including the priority output destination determination unit 26 and the logic negation unit 27 receives the load detection signals P ₁ and P ₂ generated by the connection state detection units 14 ₁ and 14 _{2 and} outputs a predetermined output. The output terminal to which the output voltage is supplied is determined based on the power supply priority order of the terminals. That is, when the load device 70 ₂ to the output terminal 13 ₂ is connected, preferentially output destination determination section 26 does not operate, 13 ₂ is determined as an output terminal to which the output voltage is supplied by the logic negation unit 27, switch section 12 ₂ is turned on. Specifically, the p-channel MOSFET21 is turned on, the n-channel MOSFET68 is turned through a resistor 64, while the gate potential of the p-channel MOSFET67 of the switch section 12 ₂ is lowered, the p-channel MOSFET58 is the remains off Become.

On the other hand, when the load device 70 ₁ to the output terminal 13 ₁ is connected, operates priority output destination determination section 26, 13 ₁ as an output terminal to which the output voltage is supplied by the priority destination determining unit 26 is determined, the switch part 12 ₁ is turned on. At this time, the switch section 12 ₂ immediately before is in the ON state, the switch unit 12 ₁ is exclusively turned on by the logic negation unit 27, the switch section 12 ₂ is turned off. Specifically, the gate potentials of the p-channel MOSFET 63 and the n-channel MOSFET 68 become the ground level, the n-channel MOSFET 68 and the p-channel MOSFET 67 are turned off, and the p-channel MOSFET 63 and the n-channel MOSFETs 59 and 62 are turned on.

  Simultaneously with such determination of the output terminal, the control unit 11 identifies a predetermined output voltage at the determined output terminal, and outputs an output voltage instruction signal corresponding to the identified output voltage to the voltage conversion unit 10. To do.

On the other hand, the voltage conversion unit 10 converts the voltage from the power source 30 into an output voltage corresponding to the output terminal determined by the control unit 11. Specifically, if 13 ₂ as an output terminal of the output voltage is supplied is determined by the logical negation unit 27, without operation priority destination determining unit 26, the voltage setting of the boost part 80 is resistor 53 The output voltage is determined by the resistor 54 and the resistor 55. On the other hand, if the 13 ₁ as an output terminal to which the output voltage is supplied by the priority destination determining unit 26 has been determined, since the p-channel MOSFET63 and n-channel MOSFET59 and n-channel MOSFET62 is turned on, resistor 55 is n-channel Shorted by the MOSFET 59, the output voltage of the booster 80 is converted into an output voltage determined only by the resistors 53 and 54.

Next, the switch units 12 ₁ and 12 ₂ selectively switch to the determined output terminal to supply the output voltage. Specifically, when the determined output terminal is an output terminal 13 _2, since the p-channel MOSFET67 is turned on, the output voltage is output only to the connector 69 ₁ load device 70 ₂ is connected . Further, when the determined output terminal is an output terminal 13 _1, because p-channel MOSFET58 is turned on, the output only to the output terminal 13 _1.

Next, the load device 70 ₂ to the output terminal 13 ₂ via the connector 69 ₂ are connected, when the output of the booster 80 is supplied to an output terminal 13 _2, output through the connector 69 ₁ terminal 13 It will be described which is additionally connected to the load device 70 ₁ to _1. When the load device 70 ₁ to the output terminal 13 ₁ is connected, the control right of the n-channel MOSFET68 and p-channel MOSFET63 output terminal 13 ₁ has an output voltage n-channel MOSFET59 is turned on by the voltage converter 10 at the same time is converted into an output voltage set to the output terminal 13 _1, the p-channel MOSFET67 is off, p-channel MOSFET58 is turned on, the output terminal is switched to the output terminal 13 ₁ from the output terminal 13 _2. Furthermore, when removing the load device 70 _first output terminal 13 ₁ in this state, n-channel MOSFET68 is on, and the p-channel MOSFET63 is turned off, the output destination of the boosting unit 80 to the output terminal 13 ₂ from the output terminal 13 ₁ Switch. It switched to the voltage set output voltage to the output terminal 13 ₂ simultaneously.

  In addition, when the load device is continuously connected to each of the two output terminals, power is supplied to one output terminal having a higher power supply priority order based on a predetermined power supply priority order and connected to the output terminal. After power supply to the loaded load device (for example, a mobile phone) is completed, the power supply output terminal may be switched to the other output terminal to supply power to the output terminal. In this case, even when power is being supplied to the other output terminal and the mobile phone connected to one of the output terminals is connected and used for recharging, the mobile phone must be connected. It is preferable that the power supply to the other output terminal is not interrupted as long as it is released and connected again. Thereby, it is possible to avoid interruption of power supply to a load device having a low power supply priority due to repeated charging of the load device having a high power supply priority within a short time.

In the present embodiment, the resistance by 60 and RC delay circuit consisting of capacitor 56, when the speed of the switching of the switched rate of the output voltage of the boosting unit 80 and the output terminal is different, the output power terminal of the load device 70 ₁ when until the output voltage from the connected to the terminal 13 ₁ is supplied to the output terminal 13 ₁ it is necessary to provide a delay, it is possible to adjust the delay time. Further, the RC delay circuit consisting of in the same manner as capacitor 66 resistor 75., boosted output from the power supply terminal via the connector 69 _second output terminal 13 ₂ to the load device 70 ₂ is connected is outputted to the output terminal 13 ₂ It is possible to arbitrarily change the delay time until completion.

As mentioned above, although preferred embodiment of this invention was described, this embodiment can be variously changed in the range which does not deviate from the summary of this invention. Specifically, in the present embodiment, the switches 21 and 12 _{1 to} 12 _N are MOSFETs, but may be bipolar transistors. Moreover, it is not necessary to be a semiconductor switch, and a mechanical relay may be used.

In the present embodiment, the load detection signals P _{1 to} P _N indicating whether or not the load device is connected appear as a change in potential, but may be in the form of a change in electrical resistance. It may be a mechanical signal that turns on a mechanical switch incorporated in the output connector when the output connector is fitted to the output terminal.

In addition, the power supply priority is set in advance for the output terminal itself so that the load device with the higher power supply priority is connected to the route with the lower output path number in advance. The setting rule is not particularly limited. When the control unit 11 is constituted by a microcomputer, the power supply priority setting of the output terminal can be set and changed arbitrarily and easily by creating a correspondence table of output path numbers and power supply priority in the microcomputer.
In the third embodiment, an example of the booster circuit is shown as an example of the voltage conversion unit 10, but this is a design matter determined by the level of the power supply 30 and the operating voltages of the load devices 70 ₁ and 70 _2. Yes, it is not limited to a booster circuit, and a voltage step-up / step-down voltage converter circuit configuration can be adopted.

It is a circuit block diagram of power supply device 1A. It is a circuit block diagram of the power supply device 1B. It is a circuit block diagram of power supply device 1C.

Explanation of symbols

7 ... switch control unit, 10 ... voltage conversion unit, 11 ... control unit, ₁₂ 1 to 12 N _... switch unit, ₁₃ 1 to 13 N _... output terminal, ₁₄ 1 to 14 N _... connection status detecting unit, 22 ... switch, 23 ₁ to 23 _N ... Diode, 24 _{1 to} 24 _N ... Resistance, 26... Priority output determination unit, 27.

Claims (7)

A voltage converter that converts an input voltage from the power source into a predetermined output voltage;
A connection state detection unit for detecting a connection state of the load device at a plurality of output terminals and generating a load detection signal corresponding to the connection state;
In response to receiving the load detection signal generated by the connection state detection unit, the output voltage is supplied among the plurality of output terminals based on a predetermined power supply priority order of the plurality of output terminals. A control unit that determines two output terminals;
First switching means for selectively switching and supplying the output voltage to the determined one output terminal;
A power supply apparatus comprising:   The power supply apparatus according to claim 1, wherein the control unit controls the voltage conversion unit so that the predetermined output voltage becomes a voltage value predetermined for the one output terminal.   When the load device is connected to one or more of the plurality of output terminals based on the load detection signal from the connection state detection unit for supplying the output voltage to the one output terminal. The power supply device according to claim 1, wherein the power supply device starts when it is determined. A second switching means connected between the power source and the voltage converter;
The power supply apparatus according to claim 3, wherein the second switching unit includes a switch and a switch control unit that controls a switching state of the switch based on the load detection signal.   The switch control unit switches the switch when it is determined that the load device is connected to at least one of the plurality of output terminals based on the load detection signal for each of the plurality of output terminals. 5. The power supply device according to claim 4, further comprising a negative logic OR circuit that is turned on.   The control unit includes: a priority output destination determination unit that determines, as the one output terminal, an output terminal having a higher power supply priority among the output terminals from which connection of the load device is detected; and the priority output destination 5. A power source according to claim 1, further comprising: a logic negation unit that exclusively switches the output voltage to the one output terminal in accordance with a control signal from the determination unit. apparatus. A voltage conversion step in which the voltage conversion unit converts an input voltage from the power source into a predetermined output voltage; and
A connection state detection unit that detects a connection state of the load device at a plurality of output terminals and generates a load detection signal corresponding to the connection state; and
In response to reception of the load detection signal generated by the connection state detection unit, the control unit determines whether the output voltage among the plurality of output terminals is based on a predetermined power feeding priority of the plurality of output terminals. A control step for determining one output terminal to be supplied;
A switching step in which a first switching means selectively switches and supplies the output voltage to the determined one output terminal;
An output switching method comprising:

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