JP2010017063A - Electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a circuit scale because an expansion in circuit scale and a cost increase are brought by constituting a switching circuit of power supply and an overvoltage protecting circuit individually and by using a plurality of switch means such as a FET in an electronic equipment capable of being connected to a plurality of power supplies. <P>SOLUTION: The electronic equipment is constituted using a common circuit using a circuit provided with the switch means which switches to either a conductive state or an interrupting state for switching the power supply and a circuit provided with the switch means which switches to either the conductive state or the interrupting state for protecting an overvoltage, and controls the switch means. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device that can be connected to a plurality of power supplies and includes a power supply switching and overvoltage protection circuit.

Generally, an electronic device that can be connected to a plurality of power supplies is provided with a power supply switching circuit. Furthermore, if an overvoltage is applied to the power input terminal, there is a risk that circuit components constituting the load may be destroyed, and thus an overvoltage protection circuit may need to be added. As a specific example of this overvoltage protection circuit, when it is detected that the voltage of the output unit connected to the load is higher than a predetermined voltage, the FET connected to the input terminal is turned off, Patent Document 1 discloses an overvoltage protection circuit that prevents overvoltage from being applied to a load.
JP 2006-33943 A

  In the prior art, when a plurality of power supplies are switched, a switching means such as an FET that switches between a conductive state and a cut-off state is used in a power supply switching circuit. In the overvoltage protection circuit of the prior art, switch means such as an FET that switches between a conduction state and a cutoff state has been used.

  Conventionally, in an electronic device that can be connected to a plurality of power supplies, a power supply switching circuit and an overvoltage protection circuit are configured separately, and a plurality of switching means such as FETs are used, which increases circuit scale and costs. It was.

  The present invention solves the above-mentioned problem. By configuring the power supply switching circuit and the overvoltage protection circuit with a common circuit, the power supply switching and the overvoltage protection are controlled while suppressing the expansion of the circuit scale and the cost increase. It provides a means that can be used.

The control means of the first invention includes a first input terminal connectable to the first power supply, a second input terminal connectable to the second power supply, an output unit connected to the load, and a conduction state. Switch means for switching to any one of the cut-off states and controlling the output section voltage; voltage level detecting means for detecting the voltage level of the first input terminal; connecting the output section and the second input terminal; Connecting the first input terminal to the input part of the switch means, connecting the second input terminal to the control terminal of the switch means, and the output part of the voltage level detection means,
When a second power source is connected to the second input terminal, the switch means is turned off, and a voltage based on an applied voltage of the second power source is output to the output unit, and the second input terminal When the second power supply is not connected and the voltage of the first input terminal to which the first power supply is connected is below a predetermined level, a voltage based on the applied voltage of the first power supply is output to the output unit. As described above, when the switch means is controlled by the output of the voltage level detecting means and the voltage of the first input terminal exceeds a predetermined level, a voltage based on the applied voltage of the first power supply is applied to the output section. The switch means is controlled by the output of the voltage level detecting means so that it is not output.
The control means of the second invention includes a first input terminal connectable to the first power supply, a second input terminal connectable to the second power supply, an output unit connected to the load, and a conduction state. Switch means for switching to any one of the cut-off states and controlling the output section voltage; voltage level detecting means for detecting the voltage level of the first input terminal; connecting the output section and the second input terminal; Connecting the first input terminal to the input part of the switch means, connecting the second input terminal to the control terminal of the switch means, and the output part of the voltage level detection means,
When the first power source is not connected to the first input terminal and the second power source is connected to the second input terminal, a voltage based on an applied voltage of the second power source is the output unit. Output to
In a state where the second power supply is not connected to the second input terminal, the switch means is controlled by the output of the voltage level detection means, whereby the first input terminal to which the first power supply is connected Is less than or equal to a first predetermined level, a voltage based on the voltage applied to the first power source is output to the output unit, and the voltage at the first input terminal to which the first power source is connected is the first voltage. When a predetermined level of 1 is exceeded, a voltage based on the applied voltage of the first power supply is not output to the output unit,
When the second power source is connected to the second input terminal and the voltage of the first input terminal does not reach a second predetermined level lower than the first predetermined level, the switch means is cut off. When a voltage based on an applied voltage of the second power supply is output to the output unit, and the voltage of the first input terminal reaches the second predetermined level and is equal to or lower than the first predetermined level, Controlling the switch means so that a voltage based on an applied voltage of the first power supply is output to the output unit;
When the second power source is connected to the second input terminal and the voltage of the first input terminal exceeds the first predetermined level, a voltage based on the applied voltage of the first power source is the output. So that the switch means is shut off by the output of the voltage level detection means so that a voltage based on the applied voltage of the second power supply is output to the output part. Control is performed by the output of the voltage level detection means. The control means of the third invention is characterized in that an FET is used as the switch means for switching to either the conduction state or the cutoff state of the first invention or the second invention and controlling the output section voltage.

  According to the present invention described above, in an electronic device that can be connected to a plurality of power supplies, by configuring a power supply switching circuit and an overvoltage protection circuit with a common circuit, while suppressing an increase in circuit scale and cost increase, Controls power switching and overvoltage protection.

  The objects, features and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.

  With reference to FIG. 1, a power supply control circuit 1 in which a power supply switching circuit and an overvoltage protection circuit are configured by a common circuit will be described.

  In the power supply control circuit 1, Q 11 is a P-channel type MOSFET (hereinafter referred to as “transistor Q 11”), and T 11 is a first input terminal that can be connected to the AC adapter 101. The input terminal T11 is connected to the source terminal of the transistor Q11 and the anode terminal of the diode D11, and the cathode terminal of the diode D11 is connected to the resistor R13.

  R11 and R12 are voltage dividing resistors provided between the first input terminal T11 and the ground (GND). The voltage dividing points of the voltage dividing resistors R11 and R12 are connected to the input terminal of the controller IC 21 for detecting the voltage level. The The IC 21 is a controller IC in which the output terminal of the IC 21 becomes 0V when the voltage level of the input terminal is equal to or lower than a predetermined threshold (1V), and the output terminal of the IC 21 becomes high impedance when the voltage level exceeds 1V. The output terminal of the controller IC 21 is connected to the resistors R13 and R14, and the other end of R14 is connected to the gate terminal of the transistor Q11 and the cathode terminal of the diode D12. The drain terminal of the transistor Q11 is connected to the anode terminal of the diode D14, and the cathode terminal of the diode D14 is connected to the output unit T13. T 12 is a second input terminal that can be connected to the cradle 102. The input terminal T12 is connected to the anode terminal of the diode D12 and the anode terminal of the diode D13, and the cathode terminal of the diode D13 is connected to the cathode terminal of the diode D14 and the output unit T13. The output unit T13 is connected to a load 103 such as a circuit component. The cradle 102 corresponds to an expansion device that can supply power to the digital camera by mounting an electronic device that is a digital camera, and is an AC that can apply a DC voltage to the camera from a commercial power source. A type of adapter.

  Next, the circuit operation of the power supply control circuit 1 having the above-described circuit configuration will be described with reference to FIG.

  When the input voltage Vin2 (5 V) is applied from the cradle 102 to the second input terminal T12, a voltage is applied to the gate terminal of the transistor Q11 via the diode D12, and the transistor Q11 is turned off. That is, the input voltage Vin2 is output to the output unit T13 via D13.

  When the cradle 102 is not connected and the input voltage Vin1 (5 V) is applied from the AC adapter 101 to the first input terminal T11, a current flows through the voltage dividing resistors R11 and R12, and the controller IC 21 detects the voltage level. A voltage is applied to the input terminal. When the voltage at the first input terminal T11 is 5V, the voltage dividing resistors R11 and R12 are set so that the voltage dividing point of the voltage dividing resistors R11 and R12 is 1V. When the level of the input voltage is detected by the controller IC21 and the level is equal to or lower than a predetermined threshold (1V), the output voltage of the IC21 becomes 0V, and the voltage 0V is applied to the gate terminal of the transistor Q11 via the resistor R14. Q11 is turned on. That is, the input voltage Vin1 is output to the output unit T13 via the transistor Q11 and the diode D14.

  When the input voltage Vin1 exceeds 5V from the AC adapter 101 and is applied to the first input terminal T11, the voltage level of the input terminal of the controller IC21 exceeds a predetermined threshold (1V), and the output of the IC21 is output. The terminal is high impedance. Then, the input voltage Vin1 is applied to the gate terminal of the transistor Q11 via the diode D11, the resistor R13, and the resistor R14, the gate terminal and the source terminal of the transistor Q11 become substantially the same potential, the transistor Q11 is turned off, The input voltage Vin1 is not output to the output unit T13. That is, when the output voltage Vin1 of the AC adapter 101 is abnormally high, the voltage of Vin1 is not output to the output unit T13.

  Thus, when the cradle 102 is connected to the second input terminal T12, the input voltage Vin2 from the cradle 102 is given priority regardless of whether or not the AC adapter 101 is connected to the first input terminal T11. Is output to the output unit T13. When the cradle 102 is not connected to the second input terminal T12, the input voltage Vin1 from the AC adapter 101 is output to the output unit T13 depending on whether the AC adapter 101 is connected to the first input terminal T11. Or not output. Furthermore, when the output voltage Vin1 of the AC adapter 101 is abnormally high, the voltage of Vin1 is not output to the output unit T13.

  Next, referring to FIG. 2, the circuit operation of the power supply control circuit 110 will be described below as another embodiment.

  In FIG. 2, the same parts as those in FIG. That is, the difference from FIG. 1 is that an AC adapter 301 is connected to the input terminal T11 instead of the AC adapter 101, and R31 and R32 are connected instead of the voltage dividing resistors R11 and R12. . Note that the output voltage of the AC adapter 301 is set higher than that of the AC adapter 101. When the AC adapter 301 is not connected and the input voltage Vin2 (5 V) is applied from the cradle 102 to the second input terminal T12, the input voltage Vin2 is output to the output unit T13 via D13.

  Further, when the cradle 102 is not connected and an input voltage Vin3 equal to or lower than a first predetermined level V1 (for example, 5.7 V) is applied from the AC adapter 301 to the first input terminal T11, the voltage dividing resistors R31 and R32 are applied. A current flows and a voltage is applied to the input terminal of the controller IC 21 that detects the voltage level. When the voltage at the first input terminal T11 is 5.7V, the voltage dividing resistors R31 and R32 are set so that the voltage dividing point of the voltage dividing resistors R31 and R32 is 1V. When the level of the input voltage is detected by the controller IC21 and the level is equal to or lower than a predetermined threshold (1V), the output voltage of the IC21 becomes 0V, and the voltage 0V is applied to the gate terminal of the transistor Q11 via the resistor R14. Q11 is turned on. That is, the input voltage Vin3 is output to the output unit T13 via the transistor Q11 and the diode D14. When the input voltage Vin3 exceeds the voltage 5.7V from the AC adapter 301 and is applied to the first input terminal T11, the voltage level of the input terminal of the controller IC21 exceeds a predetermined threshold (1V). The output terminal is high impedance. Then, the input voltage Vin3 is applied to the gate terminal of the transistor Q11 via the diode D11, the resistor R13, and the resistor R14, the gate terminal and the source terminal of the transistor Q11 become substantially the same potential, the transistor Q11 is turned off, The input voltage Vin3 is not output to the output unit T13. That is, when the output voltage Vin3 of the AC adapter 301 is abnormally high, the voltage of Vin3 is not output to the output unit T13.

  Next, the case where the input voltage Vin3 is applied from the AC adapter 301 to the first input terminal T11 and the input voltage Vin2 (5 V) is applied from the cradle 102 to the second input terminal T12 will be described with reference to FIG. explain.

  When the input voltage Vin3 from the AC adapter 301 does not reach the second predetermined level V2 (for example, 5.4V), the input voltage Vin2 (5V) from the cradle 102 is applied to the gate terminal of the transistor Q11 via the diode D12. Is applied to turn off the transistor Q11. That is, the input voltage Vin2 is output to the output unit T13 via D13.

  When the input voltage Vin3 from the AC adapter 301 is 5.4 V or more and 5.7 V or less, the input voltage Vin2 (5 V) from the cradle 102 is forwarded through the diode D12 to the gate terminal of the transistor Q11. A voltage (4.5 V) dropped by the voltage VF (0.5 V) is applied. Then, when the voltage at the gate terminal of the transistor Q11 becomes lower than the voltage at the source terminal by a predetermined voltage Vth (−0.9 V), the transistor Q11 is turned on. The predetermined voltage Vth (−0.9 V) is a gate threshold voltage at which the transistor Q11 is turned on when the voltage at the gate terminal of the transistor Q11 becomes 0.9 V or less than the voltage at the source terminal. That is, the input voltage Vin3 is output to the output unit T13 via the transistor Q11 and the diode D14.

  When the input voltage Vin3 exceeds the voltage 5.7V from the AC adapter 301 and is applied to the first input terminal T11, the voltage level of the input terminal of the controller IC21 exceeds a predetermined threshold (1V). The output terminal is high impedance. Then, the input voltage Vin3 is applied to the gate terminal of the transistor Q11 via the diode D11, the resistor R13, and the resistor R14, the gate terminal and the source terminal of the transistor Q11 are almost at the same potential, and the transistor Q11 is turned off. That is, the input voltage Vin3 is interrupted and the input voltage Vin2 is output to the output unit T13 via D13. That is, when the output voltage Vin3 of the AC adapter 301 is abnormally high, the voltage of Vin3 is not output to the output unit T13.

  Needless to say, the voltage level for controlling the transistor Q11 changes due to variations in the forward voltage VF of the diode, the gate threshold voltage of the transistor Q11, and the characteristics of the controller IC21 and the like. In addition, there is a case where the voltage level for detecting an abnormal high voltage is given a margin or not like the control when the input voltage Vin3 from the AC adapter 301 is 5.4 V or more and 5.7 V or less. .

  As described above, in the power supply control circuit that can be connected to a plurality of power supplies, the power supply switching circuit and the overvoltage protection circuit can be configured by a common circuit. Then, it is possible to control power supply switching and overvoltage protection while suppressing an increase in circuit scale and cost increase.

  In the above-described embodiment, for ease of explanation, a P-channel MOSFET, which is a semiconductor switching element that is turned on when a gate voltage is equal to or lower than a predetermined threshold, is described. However, the present invention is not limited to this as long as it is a semiconductor switch that operates in the same manner. Needless to say, even when the number of power supplies to be connected is increased, a similar circuit configuration can be achieved by increasing the number of switch circuits.

It is a circuit diagram which shows the form of the power supply control circuit which is one Example of this invention. It is a circuit diagram which shows the form of the power supply control circuit which is another Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Power supply control circuit R11, R12 ... Voltage dividing resistor Q11 ... P channel type MOSFET
21 ... Controller IC for detecting the voltage level
T11, T12 ... input terminal T13 ... output part R31, R32 ... voltage dividing resistor

Claims (3)

A first input terminal connectable to a first power source;
A second input terminal connectable to a second power source;
An output connected to the load;
Switch means for switching to either the conductive state or the cut-off state to control the output unit voltage;
Voltage level detecting means for detecting a voltage level of the first input terminal;
The output part and the second input terminal are connected, the first input terminal is connected to the input part of the switch means, the second input terminal is connected to the control terminal of the switch means, and the output of the voltage level detection means Connecting means for connecting the parts,
When a second power source is connected to the second input terminal, the switch means is turned off, and a voltage based on an applied voltage of the second power source is output to the output unit,
Based on the applied voltage of the first power source when the second power source is not connected to the second input terminal and the voltage of the first input terminal to which the first power source is connected is below a predetermined level. The switch means is controlled by the output of the voltage level detection means so that a voltage is output to the output unit, and when the voltage of the first input terminal exceeds a predetermined level, the voltage applied to the first power source is An electronic apparatus, wherein the switch means is controlled by the output of the voltage level detection means so that a voltage based on the output voltage is not output to the output unit. A first input terminal connectable to a first power source;
A second input terminal connectable to a second power source;
An output connected to the load;
Switch means for switching to either the conductive state or the cut-off state to control the output unit voltage;
Voltage level detecting means for detecting a voltage level of the first input terminal;
The output part and the second input terminal are connected, the first input terminal is connected to the input part of the switch means, the second input terminal is connected to the control terminal of the switch means, and the output of the voltage level detection means Connecting means for connecting the parts,
When the first power source is not connected to the first input terminal and the second power source is connected to the second input terminal, a voltage based on an applied voltage of the second power source is the output unit. Output to
In a state where the second power supply is not connected to the second input terminal, the switch means is controlled by the output of the voltage level detection means, whereby the first input terminal to which the first power supply is connected Is less than or equal to a first predetermined level, a voltage based on the voltage applied to the first power source is output to the output unit, and the voltage at the first input terminal to which the first power source is connected is the first voltage. When a predetermined level of 1 is exceeded, a voltage based on the applied voltage of the first power supply is not output to the output unit,
When the second power source is connected to the second input terminal and the voltage of the first input terminal does not reach a second predetermined level lower than the first predetermined level, the switch means is cut off. When a voltage based on an applied voltage of the second power supply is output to the output unit, and the voltage of the first input terminal reaches the second predetermined level and is equal to or lower than the first predetermined level, Controlling the switch means so that a voltage based on an applied voltage of the first power supply is output to the output unit;
When the second power source is connected to the second input terminal and the voltage of the first input terminal exceeds the first predetermined level, a voltage based on the applied voltage of the first power source is the output. So that the switch means is shut off by the output of the voltage level detection means so that a voltage based on the applied voltage of the second power supply is output to the output part. Electronic equipment controlled by output of voltage level detection means.   3. The electronic apparatus according to claim 1, wherein the switch means is an FET.