JP2005051922A - Power supply system and power supply method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To offer a simple, reliable, and universal power supply system and a power supply method. <P>SOLUTION: This power supply system is equipped with a power unit which has a converter for converting input voltage into output, and a load device which has load to be supplied with power from the above converter and is capable of mounting on and removal from the above power unit. The above load device is equipped with the first storage means which stores the characteristic information of the above load, and the above power unit is equipped with an interface which is connected to the above firs storage means, and the above converter sets the properties of the above converter, on the basis of the operation information based on the above property information. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention provides a power supply system including a power supply device including a converter that converts an input voltage into an output, and a load device that includes a load that is supplied with power from the converter and is detachable from the power supply device. About.

A conventional power supply system is, for example, an AC adapter and a notebook personal computer. And the structure is as follows.
The input of the AC adapter that is a power supply device is connected to an AC input voltage, and the output of the AC adapter is connected to a notebook personal computer that is a load device. The AC adapter converts the AC input voltage into a DC voltage and supplies power to the notebook personal computer.

A notebook personal computer may be used after disconnecting from the AC adapter. In such a case, it is recommended that the AC adapter be disconnected from the AC input voltage, but since it is cumbersome, it is common to take a usage form that does not disconnect it.
In such a case, the AC adapter is connected to the notebook personal computer or disconnected from the notebook personal computer while being always connected to the AC input voltage.

  Further, for example, the power supply system of the AC adapter and the digital camera is connected to the digital camera in a state where the AC adapter is always connected to the AC input voltage, as in the power supply system of the notebook personal computer. Disconnect from a digital camera.

  Furthermore, for example, the power supply system of an AC adapter and a portable telephone is connected to the portable telephone in a state where the AC adapter is always connected to an AC input voltage, like the power supply system of a notebook personal computer. Disconnect from your mobile phone.

  Then, an AC adapter is formed for each load device such as an AC adapter dedicated to a notebook personal computer, an AC adapter dedicated to a digital camera, and an AC adapter dedicated to a portable phone.

  In such a conventional power supply system, a user who is a user of a load device can connect a power adapter by connecting a dedicated adapter to the load device without having detailed knowledge of the characteristics of the power supply device and the load device. The device and the load device can be operated normally.

  On the other hand, if a user supplies power to each load device from a power supply device composed of a general-purpose variable voltage source device without using a dedicated adapter, an unexpected accident may occur. For example, a power supply device and a load device emit smoke. This is due to the fact that the power supply device and the load device have various specifications other than the rated voltage and rated current as shown on the display label.

  For example, the battery mounted on the load device is charged with a constant current by using the overcurrent limiting characteristic of the power supply device. By doing so, the charging circuit in the load device is simplified.

  In some cases, the size of the power supply device may be reduced by limiting the peak load time that occurs when the hard disk mounted on the load device is activated. Specifically, the power supply apparatus having the peak load output capacity is large, but the size of the power supply apparatus can be reduced by limiting the peak load time and suppressing the heat generation of the power supply apparatus.

  When the power supply device and the load device generate smoke under the usage conditions recommended by the set manufacturer, the set manufacturer is liable for damages to the user. For this reason, a dedicated AC adapter is often prepared for each load device.

  Furthermore, a set manufacturer that supplies a load device and a dedicated power supply device for the load will perform an operation test under the worst-case condition, assuming usage patterns based on detailed knowledge of the characteristics of the load device and the power supply device. is doing. For example, the set maker connects all the options that can be connected to the main body to a notebook personal computer, and checks whether it can be used continuously for several months under the condition of a temperature of 40 degrees.

  In addition, the set maker performs user marketing and plans the characteristics of the load device and the power supply device. For example, a set maker plans whether to adopt a high-speed and high-power consumption CPU or a low-speed and low-power consumption CPU for a notebook personal computer. Furthermore, the set maker plans whether to adopt a small and high-priced dedicated AC adapter or a large and low-priced dedicated AC adapter. On the other hand, products such as notebook personal computers (load devices and power supply devices) have a short life cycle.

  Furthermore, in a product such as a notebook personal computer, the compatibility between the load device and the power supply device greatly affects reliability, size, and cost. And the specification of the power supply device which is the key is a lump of know-how, and is generally not disclosed.

  The load device is manufactured by a set maker, but the power supply device is generally a business model manufactured by a subcontracted power supply manufacturer.

  Furthermore, the conventional power supply system has a plug and play function (see, for example, Patent Document 1).

  Moreover, the conventional electric power supply system changes the characteristic of a converter based on the instruction | command from a load apparatus (for example, refer patent document 2).

Japanese Patent No. 3268492 Japanese Patent No. 3415263

  In such a conventional power supply system, a user can use a plurality of AC adapters such as an AC adapter dedicated to a notebook personal computer, an AC adapter dedicated to a digital camera, and an AC adapter dedicated to a portable phone. There is a problem that it is expensive and cumbersome. And if there is a mistake in the combination of the load device and the dedicated adapter, there is a problem that the power supply device and the load device fail.

In general, since the AC adapter is always connected to an AC input voltage, a space for arranging a plurality of AC adapters is required, which is inconvenient. Often, we find a usage pattern in the saddle wiring.
Furthermore, when a plurality of AC adapters are always connected to an AC input voltage, there is a problem that standby power loss when the AC adapter is not used increases. The increase in standby power has a serious adverse effect on the global environment.

  Furthermore, there is a problem that waste is easily increased without using the electrical life of the devices (power supply device and load device). In particular, there are many power supply devices that have similar output specifications. However, the set maker has the user purchase many power supply devices together with the load device in a short life cycle.

  Further, the user cannot freely determine the combination of the load device and the power supply device, and there is a problem that the user is restricted to the usage pattern assumed by the set manufacturer. For example, even in situations where it is desired to use a small AC adapter such as a business trip, a large AC adapter often has to be used.

  An object of the present invention is to solve the above-described problems, and to provide a simple, highly reliable, and general-purpose power supply system and power supply method.

The present invention which achieves such an object is as follows.
(1) In a power supply system including a power supply device having a converter that converts an input voltage into an output, and a load device that has a load to which power is supplied from the converter and is detachable from the power supply device. The load device includes first storage means for storing characteristic information of the load, the power supply device includes an interface connected to the first storage means, and the converter is configured to convert the conversion based on operation information based on the characteristic information. A power supply system for setting the characteristics of the vessel.

(2) The power supply system according to (1), wherein the converter is stopped when the interface and the first storage unit are disconnected.

(3) The power supply system according to (1), wherein the power supply device includes second storage means for storing the characteristic information or the operation information and holding a value when the converter operates. .

(4) The power supply device includes an auxiliary output that supplies power to the first storage unit, and operates the converter based on a confirmation signal from the load device to the power supply device (1). The power supply system described.

(5) In a power supply system including a power supply device including a converter that converts an input voltage into an output, and a load device that includes a load that is supplied with power from the converter and is detachable from the power supply device. The power supply apparatus includes first storage means for storing converter characteristic information of the converter, the load apparatus includes second storage means for storing load characteristic information of the load, and the converter includes the load characteristic information. And a characteristic of the converter based on operation information based on the converter characteristic information.

(6) In a power supply system including a power supply device having a converter that converts an input voltage into an output, and a load device that has a load to which power is supplied from the converter and is detachable from the power supply device. The power supply system includes storage means for storing characteristic information of the converter, and the load sets a load characteristic based on operation information based on the characteristic information.

(7) A first power supply device having a first converter that converts a first input voltage into a first output, and a second converter that converts a second input voltage into a second output, the first power supply device And a second power supply device detachable from the power supply system, wherein the first power supply device includes storage means for storing characteristic information of the first converter, and the second power supply device is based on the characteristic information. A power supply system that sets characteristics of the second converter based on operation information.

(8) Power of a power supply system including a power supply device having a converter that converts an input voltage into an output, and a load device that has a load supplied with power from the converter and is detachable from the power supply device A power supply method comprising: a step of communicating characteristic information of the load from the load device to the power supply device; and a step of supplying power to the load based on operation information based on the characteristic information.

(9) Power of a power supply system including a power supply device having a converter that converts an input voltage into an output, and a load device that has a load supplied with power from the converter and is detachable from the power supply device A power supply method comprising: a step of communicating operation information based on characteristic information of the load from the load device to the power supply device; and a step of supplying power to the load based on the operation information.

(10) Power of a power supply system including a power supply device having a converter that converts an input voltage into an output, and a load device that has a load supplied with power from the converter and is detachable from the power supply device In the supply method, connecting the ground potential of the power supply device and the ground potential of the load device, connecting the output of the converter to the load, and supplying an auxiliary output from the power supply device to the load device The characteristics of the converter and the characteristics of the load are set based on operation information based on the load characteristic information and the converter characteristic information, and a confirmation signal is communicated from the load device to the power supply device, A power supply method comprising: a converter supplying power to the load.

  As described above, according to the present invention, a simple, highly reliable, and general-purpose power supply system can be provided. In addition, a simple, highly reliable, and general-purpose power supply method can be provided.

  Further, since the user can supply power to a plurality of types of load devices with one power supply device, the space for arranging the power supply device can be reduced. And since there is no need to carry out a foot-strip wiring, it becomes simple and reliable, and the aesthetics are also suitable.

  Furthermore, even if there is a connection error, the converter stops outputting, so that the power supply device and the load device do not fail.

  In addition, the number of power supply devices that are always connected to the outlet is reduced, and standby power is reduced. Furthermore, the power supply device can be used up to the electrical life.

  In addition, set makers can concentrate on developing their own load devices. By manipulating the characteristic information stored in the storage means, it becomes possible to perform a virtual test between the load device and the power supply device, and the cost and time spent for these operation tests can be reduced.

  Also, the characteristic information stored in the storage means can be updated via a network even after product shipment. In this way, the characteristic information can be updated, and the reliability of the device can be further increased.

  Furthermore, power supply manufacturers can easily share parts and mass-produce power supply devices, and can provide power supply devices at low cost. Moreover, the cost required for development can be suppressed.

  Hereinafter, the present invention will be described in detail with reference to FIG. FIG. 1 is a configuration diagram showing an embodiment of a power supply system according to the present invention.

  A feature of the embodiment of FIG. 1 is that a storage circuit 22 in the load device 7 and a control circuit 6 having an interface 13 in the power supply device 8 are provided.

  In the figure, the common potential COM and the ground potential GND are set as the common potential of the power supply system. The main converter 3 is a circuit that converts the input voltage Vi on the primary side into the voltage V2 on the secondary side.

  The step-down converter 4 as a converter is a circuit that converts the voltage V2 into the voltage V3 based on the drive voltage VG. Further, the voltage V3 becomes the output voltage Vo via the resistor R1 and is connected to the load 20 in the load device 7. The output voltage Vo and the load current Io supply power to the load 20. The voltage generated in the resistor R1 becomes the voltage V5 through the amplifier U1. The voltage V5 is proportional to the load current Io. Furthermore, since the voltage generated in the resistor R1 can be ignored as compared with the voltage V3 and the output voltage Vo, the output voltage Vo is substantially equal to the voltage V3.

  Furthermore, the storage means 22 in the load device 7 stores characteristic information of the load 20. For example, specifications of a power supply device suitable for the load 20 and a simulation model of the load 20 are included. Specifically, the output voltage value suitable for the load 20, the overvoltage set value suitable for the load 20, the overcurrent set value / overcurrent allowable time suitable for the load 20, the overtemperature value suitable for the load 20, and the like. The storage means 22 is formed of a non-volatile element that does not erase the memory even when it is non-conductive, such as a MASKROM and a flash EEPROM.

  The storage unit 22 is connected to the interface 13 in the power supply device 8 via a resistor R4, a resistor R5, a resistor R6, and a resistor R7. The characteristic information of the storage means 22 becomes a signal data through the resistors R4 and R5, and is communicated to the interface 13 through the resistors R6 and R7.

  Further, the control circuit 6 has an interface 13. The interface 13 is connected to the non-inverting input terminal of the error amplifier U2 via the voltage data U20 in the storage means 10 and the digital / analog converter U12. Further, the inverting input terminal of the error amplifier U2 is connected to the voltage V3, and the output V10 of the error amplifier U2 becomes a drive signal VG via the modulation circuit U16 and is connected to the step-down converter 4. Then, the error amplifier U2 controls the step-down converter 4 so that the voltage V3, that is, the output voltage Vo becomes a voltage based on the value V20 of the voltage data U20.

  Furthermore, the interface 13 is connected to one input of the comparator U3 via the overvoltage data U21 in the storage means 10. Further, the other input of the comparator U3 is connected to the voltage V3 via the analog / digital converter U11, and the output V12 of the comparator U3 is connected to the modulation circuit U16 via the IO U14. Then, the comparator U3 stops the step-down converter 4 when the voltage V3, that is, the output voltage Vo exceeds a value based on the value V21 of the overvoltage data U21.

  The interface 13 is connected to one input of the comparator U4 via the overcurrent data U22 in the storage means 10. Further, the other input of the comparator U4 is connected to the output V5 of the amplifier U1 via the analog / digital converter U10, and the output V13 of the comparator U4 is connected to the modulation circuit U16 via the IO U14. Then, the comparator U4 stops the step-down converter 4 when the voltage V5, that is, the load current Io exceeds a value based on the value V22 of the overcurrent data U22.

  Furthermore, the interface 13 is connected to one input of the comparator U5 via the overpower data U23 in the storage means 10. Further, the other input of the comparator U5 is connected to a temperature sensor U17 formed in the power supply device 8 via an analog / digital converter U13, and an output V14 of the comparator U5 is connected to a modulation circuit U16 via an I / O U14. To do. Then, the comparator U5 stops the step-down converter 4 when the value V19 of the temperature sensor, that is, the temperature of the power supply device exceeds the value based on the value V23 of the overpower data U23.

  When the interface 13 and the storage means 22 are disconnected, the interface 13 becomes invalid, and the storage means 10, the error amplifier U2, the comparator U3, the comparator U4, the comparator U5, the IO U14, and the modulation circuit U16 It becomes invalid, the step-down converter 4 stops, and the voltage V3 and the output voltage Vo stop.

  Further, the storage means 10 stores the characteristic information from the interface 13 as driving information. When the step-down converter 4 is operating, the value of the storage means 10 is held so that the value of the storage means 10 does not change. Furthermore, the storage means 10 deletes the stored operation information when the interface 13 and the storage means 22 are disconnected.

  The storage unit 12 in the power supply device 8 stores characteristic information of the step-down converter 4. For example, the allowable output voltage value of the step-down converter 4, the allowable load current value of the step-down converter 4, and the step-down converter 4. And the memory | storage means 12 is formed with the non-volatile element which a memory | storage is not erase | eliminated at the time of non-conduction like MASKROM, flash EEPROM, etc. similarly to the memory | storage means 22. FIG.

  Further, the input of the calculation unit 11 in the power supply device 8 is connected to the storage unit 10 and the storage unit 12, and the output of the calculation unit 11 is connected to the modulation circuit U 16 via the I / O U 14. Then, the calculation unit 11 determines that the voltage data U20, overvoltage data U21, overcurrent data U22, and overtemperature data U23 in the storage unit 10 are the allowable output voltage value, allowable load current value, and allowable overtemperature value in the storage unit 12. If it exceeds, step down converter 4 is stopped.

  The regulator 5 is a circuit that converts the voltage V2 into an auxiliary output Standby. Further, the auxiliary output Standby is connected to the control circuit 6 and the storage means 22 to supply power.

  Further, the auxiliary output Standby becomes a confirmation signal detect via the resistor R2 in the load device 7, and is connected to one input in the comparator U6 in the power supply device 8 and the resistor R3. The other input of the comparator U6 is connected to the reference voltage Vr, and the output of the comparator U6 is connected to the modulation circuit U16 via the I / O U14.

  The comparator U6 stops the step-down converter 4 when the confirmation signal detect is at a low level, that is, when the power supply device 8 and the load device 7 are not normally connected.

  Further, the comparator U6 releases the stop of the step-down converter 4 when the confirmation signal detect is at a high level, that is, when the power supply device 8 and the load device 7 are normally connected.

  Further, the capacitor C1 and the diode D2 are connected between the connection point between the resistors R4 and R5 and the ground potential GND, and the diode D1 is connected between the connection point between the resistors R4 and R5 and the auxiliary output standby. . Further, a capacitor C2 and a diode D4 are connected between the connection point of the resistors R6 and R7 and the ground potential GND, and a diode D3 is connected between the connection point of the resistors R6 and R7 and the auxiliary output standby. .

The operation of the embodiment of FIG. 1 will be described.
First, when the power supply device 8 and the load device 7 are halfway connected, the ground potential GND, the output voltage Vo, and the auxiliary output standby are connected, and the signal data is disconnected, the interface 13 becomes invalid. The step-down converter 4 stops, and the voltage V3 and the output voltage Vo stop. For this reason, no stress is generated in the load 20.

  Next, when the power supply device 8 and the load device 7 are completely connected, the characteristic information of the storage means 22 is communicated to the interface 13 and the interface 13 becomes valid. The characteristic information of the interface 13 becomes operation information, which is a value V20 of the voltage data U20, a value V21 of the overvoltage data U21, a value V22 of the overcurrent data U22, and a value V23 of the overtemperature data U23. Set the output characteristics. Specifically, the output voltage value, overvoltage set value, overcurrent set value, and overtemperature value of the step-down converter 4 are set. The step-down converter 4 outputs an output voltage value suitable for the load 20, an overvoltage set value suitable for the load 20, an overcurrent set value suitable for the load 20, and an overtemperature value suitable for the load 20.

  When the load device 8 is changed to another load device 8 ′, the characteristic information of the storage means 22 ′ of the load device 8 ′ is communicated to the interface 13 to become operation information, and the step down converter 4 loads the load of the load device 8 ′. An output voltage value suitable for 20 ′, an overvoltage setting value suitable for the load 20 ′, an overcurrent setting value suitable for the load 20 ′, and an overtemperature value suitable for the load 20 ′ are output.

  For example, when the load device 8 is changed from a notebook personal computer to a digital camera, the characteristics of the step-down converter 4 change from characteristics suitable for a notebook personal computer to characteristics suitable for a digital camera.

  Further, when the power supply device 8 and the load device 7 are disconnected, the interface 13 becomes invalid, the step-down converter 4 stops, the voltage V3 and the output voltage Vo stop, and the operation information stored in the storage means 10 Is erased.

  In this way, the power supply device 8 can supply power to a plurality of types of load devices. The user can normally operate the power supply device 8 and the load device 7 without detailed knowledge of the characteristics of the power supply device 8 and the characteristics of the load device 7. Further, since the set manufacturer can change the characteristics of the power supply device 8 by changing the description of the storage means 22 of the load device 7, the operation test of the product (load device and power supply device) can be simplified. Furthermore, since it is not necessary for a power supply manufacturer to manufacture a power supply device for each load device, it is easy to make components common and mass production of the power supply device, and the power supply device is low in cost.

  Further, after the operation information based on the characteristic information from the interface 13 is stored in the storage means 10, the value of the storage means 10 is held when the step-down converter 4 starts operating. Therefore, even if noise occurs in the signal data during the operation of the step-down converter 4, the value of the storage means 10 is maintained and the characteristics of the step-down converter 4 do not change, so that power can be supplied with high reliability.

  Further, the low-pass filter composed of the resistor R4, the resistor R5 and the capacitor C1, the low-pass filter composed of the resistor R6, the resistor R7 and the capacitor C2, and the diode D1, the diode D2, the diode D3 and the diode D4 are generated in the signal data. In addition to reducing the influence of external noise, the storage means 22 and the interface 13 are protected when a short circuit failure occurs between the output voltage Vo and the ground potential GND.

  Further, the output voltage Vo and the auxiliary output standby are output from the power supply device 8 to the load device 7, and the signal data and the confirmation signal detect are output from the load device 7 to the power supply device 8. If any of the connections among the output voltage Vo, the auxiliary output standby, the signal data, and the confirmation signal detect is defective, power is not supplied to the load 20. That is, the power supply device 8 and the load device 7 are integrated and coordinated by handshaking.

  Further, the power supply device 8 and the load device 7 perform a cooperative operation for duplicating communication by the action of the auxiliary output standby and the confirmation signal detect. In addition, you may supply electric power to the memory | storage means 22 from the storage battery in the load apparatus 7, etc. (not shown).

  Furthermore, when the step-down converter 4 is not capable of supplying power to the load 20, that is, when a suitable overcurrent set value exceeds the allowable load current value, the step-down converter 4 remains stopped. For this reason, no stress is generated in the load 20.

The operation at this time will be described in detail.
The characteristic information of the storage unit 22 is stored in the storage unit 10 via the interface 13. Then, the calculation unit 11 generates driving information based on the storage unit 10 and the storage unit 12. In this case, the operation information becomes 0, and the step down converter 4 stops.

Further, the power supply method of the embodiment of FIG. 1 will be described.
First, the step of communicating the characteristic information of the load 20 from the load device 7 to the power supply device 8 is executed. And the power supply device 8 produces | generates the driving information based on characteristic information. Further, the step-down converter 4 executes a step of supplying electric power to the load 20 based on this operation information.

  According to such a power supply method, it is possible to supply power to a plurality of types of load devices with a single power supply device.

Further, a highly reliable power supply method will be described.
A step of connecting the ground potential GND of the power supply device 8 and the ground potential GND of the load device 7 is executed.
Then, the step of connecting the output of the step-down converter 4 to the load 20 and supplying the auxiliary output standby from the power supply device 8 to the load device 7 is executed.

And the step which communicates the characteristic information of the said load from the said load apparatus to the said power supply device is performed.
And the characteristic of the power supply device 8 produces | generates the driving information based on characteristic information. The step-down converter 4 is set based on this operation information. Furthermore, a step of communicating a confirmation signal detect from the load device 7 to the power supply device 8 is executed.

  And the step down converter 4 performs the step which supplies electric power to the load 20 based on characteristic information.

  In such a power supply method, since the ground potential GND of the power supply device 8 and the ground potential GND of the load device 7 are connected first, malfunction or the like is unlikely to occur. Specifically, in the connector between the power supply device 8 and the load device 7, the length of the electrode assigned to the ground potential GND is formed longer than the length of the other electrodes (not shown).

  Furthermore, in such a connector, since the ground potential GND of the power supply device 8 and the ground potential GND of the load device 7 are connected until the end of the disconnection, damage to the elements is suppressed.

  In addition, such a configuration can suppress damage to the elements of the power supply apparatus 8 and the elements of the load apparatus 7 that occur when the power supply apparatus 8 and the load apparatus 7 that are supplying power to the load 20 are disconnected.

  Further, in order for the step-down converter 4 to output, two of the confirmation signal detect and the signal data are necessary, that is, since they are duplicated, no malfunction occurs.

  Furthermore, separately from the above example, if the confirmation signal detect and the signal data are encoded to increase the redundancy, the reliability is further increased.

  In addition to the above example, a module configuration (not shown) in which a plurality of step down converters 4 are connected in parallel may be used, and a combination of step down converters 4 may be appropriately selected according to the load 20. . The application range of the power supply device 8 is widened and simplified.

  In such a module configuration in which a plurality of step-down converters 4 are connected in parallel, even when there are a plurality of load devices 7, power can be supplied simultaneously.

  FIG. 2 is a block diagram showing another embodiment of the power supply system according to the present invention. The same elements as those in the embodiment of FIG.

  2 lies in the configuration of the storage means 32 and the interface 33 in the power supply apparatus 300 and the storage means 42 and the interface 43 in the load apparatus 400.

  In the figure, the storage means 32 stores the converter characteristic information of the converter 30. For example, the characteristic information includes an allowable output voltage value of the converter 30, an allowable load current of the converter 30, an allowable overtemperature value of the converter 30, and the like.

  The storage means 42 stores load characteristic information of the load 40. For example, the characteristic information includes an output voltage value suitable for the load 40, an overvoltage set value suitable for the load 40, an overcurrent set value / overcurrent allowable time suitable for the load 40, an overtemperature value suitable for the load 40, and the like. is there.

  Further, the common potential COM and the ground potential GND are set as the common potential of the power supply system. The power supply device 300 and the load device 400 are connected by an output voltage Vo, a ground potential GND, an auxiliary output standby, a confirmation signal detect, and a signal data.

  Further, the converter 30 in the power supply apparatus 300 converts the input voltage Vi into the voltage Va. The voltage Va becomes the output voltage Vo via the switch SW1. Furthermore, the converter 30 generates an auxiliary output standby and supplies power to the power supply device 300 and the load device 400. The converter 30 is controlled by the confirmation signal detect and the output Vb of the calculation unit 31.

  Further, the switch SW1 is controlled by the output Vc of the calculation unit 31. The calculation unit 31 is connected to the storage means 32. Further, the storage means 32 is connected to the signal data via the interface 33.

  A switch Q30 is connected to the confirmation signal detect. Then, the switch Q30 is turned off in the normal state, and the switch Q30 is turned on in the event of a power failure of the input voltage Vi, failure of the converter 30, or the like.

  Furthermore, the load 40 in the load device 400 is controlled by the output Vd of the comparator U40 and the output Vf of the calculation unit 41.

  One input of the comparator U40 is connected to the auxiliary output standby by way of the resistor R41. Further, the other input of the comparator U40 is connected to the reference voltage V40. The auxiliary output standby and the confirmation signal detect are connected via a resistor R40 in the load device.

  Furthermore, the switch Q40 is connected to one input of the comparator U40. Then, the switch Q40 is turned off during normal operation, and the switch Q40 is turned on when remote off.

  The calculation unit 41 is connected to the storage means 42. Further, the storage means 42 is connected to the signal data via the interface 43.

The operation of the embodiment of FIG. 2 will be described.
When the power supply device 300 and the load device 400 are disconnected, the interface 33 is disabled, the output Vc of the calculation unit 31 is disabled, the switch SW1 is turned off, and the output voltage Vo is stopped.

  When the power supply device 300 and the load device 400 are connected, the converter characteristic information stored in the storage unit 32 is stored in the storage unit 42 via the interface 33 and the interface 43. The calculation unit 41 generates operation information from the load characteristic information stored in the storage unit 32 and the converter characteristic information stored via the interface 33 and the interface 43.

  For example, when the output capacity of the converter 30 can cope with the rapid charging of the battery in the load 40, the operation information is generated so that the battery in the load 40 is rapidly charged. When the output capacity of the converter 30 cannot cope with the rapid charging of the battery in the load 40, the operation information is generated so that the battery in the load 40 is charged over time.

  In addition, the heat generation in the converter is calculated from the conversion efficiency and load of the converter, the temperature rise of the converter is calculated from the heat generation of the converter and the specific heat of the converter, and the temperature of the converter becomes the allowable overtemperature value. Calculate the time until. Then, if the time until the temperature of the converter reaches the allowable overtemperature value is 1 hour, operation information with the operation time of the load 40 as 1 hour is generated.

  Furthermore, when the power capacity of the converter 30 is not sufficient, the operation information is generated so as to partially stop the function of the load 40. As a specific example, the CD-ROM device of the notebook personal computer and the USB terminal are stopped.

  In addition, when the load device 400 having the calculation unit 41 is a device such as a computer, it is possible to easily generate advanced and complicated operation information.

  Further, the operation information generated by the calculation unit 41 is stored in the storage unit 32 via the interface 33 and the interface 43. And this driving | operation information changes the characteristic of a converter via the calculating part 31. FIG. Further, this operation information turns the switch SW1 on and off via the calculation unit 31.

  In this way, the converter 30 sets the characteristics of the converter based on the operation information. Further, the load 40 sets a load characteristic based on the operation information.

  Further, when the converter 30 does not have the ability to operate the load 40, the operation information is 0 and the switch SW1 is turned off, so that no stress is generated in the load 40.

  As described above, the functions that can be used in the load device 400 vary depending on the power supply device 300 to be connected.

A power supply method according to the embodiment of FIG. 2 will be described.
A step of supplying auxiliary output standby from the power supply device 300 to the load device 400 is executed. Further, a step of generating operation information based on the load characteristic information stored in the storage unit 32 and the converter characteristic information stored in the storage unit 42 is executed.

  And the step which the characteristic of converter 30 is set up based on driving information is performed. Moreover, the step which the characteristic of the load 40 is set based on driving | operation information is performed. Furthermore, a step of communicating a confirmation signal detect from the load device 400 to the power supply device 300 is executed.

  According to such a power supply method, similarly to the power supply method in the embodiment of FIG. 1, it is possible to supply power to a plurality of types of load devices with one power supply device.

  Moreover, although the case where the calculation part 41 produced | generated driving information was described in the above-mentioned example, the calculating part 31 can also produce | generate driving information separately from this. Since it becomes the same, description is abbreviate | omitted.

  Furthermore, the converter 30 operates when the power supply apparatus 300 and the load apparatus 400 are connected and the auxiliary output standby and the confirmation signal detect are at a high level.

  Then, at the time of remote off, the switch Q40 is turned on, the confirmation signal detect becomes low level, and the converter 30 stops.

  Therefore, when configured as in the embodiment of FIG. 2, the confirmation signal detect can also be used as a remote control.

  In addition, when there is an abnormality such as a power failure of the input voltage Vi or a failure of the converter 30, the switch Q30 is turned on, the converter 30 is stopped, the confirmation signal detect becomes low level, and the output Vd of the comparator U40 changes. The load 40 detects an abnormality.

  Therefore, when configured as in the embodiment of FIG. 2, it is possible to quickly notify the load device 400 of an abnormality such as a power failure of the input voltage Vi and a failure of the converter 30 using the confirmation signal detect.

  FIG. 3 is a block diagram showing another embodiment of the power supply system according to the present invention. Elements equivalent to those in the embodiment of FIG. 2 are denoted by the same reference numerals, and description thereof is omitted.

  The embodiment of FIG. 3 is characterized in that it is connected to a power supply device 300 as a first power supply device and a power supply device 300 ′ as a second power supply device.

  The embodiment of FIG. 1 and the embodiment of FIG. 2 have the configuration relating to the connection between the power supply device and the load device. However, as in the embodiment of FIG. It is also possible to apply to the structure which concerns on a power supply device and a 2nd power supply device.

  In the embodiment of FIG. 3, the power supply device 300 ′ has the same configuration as the power supply device 300. The output of the power supply device 300 ′ and the output of the power supply device 300 are connected in parallel. Further, the signal data is connected to the power supply device 300 ′ and the power supply device 300.

  Further, the storage means 32 in the power supply apparatus 300 stores the characteristic information of the converter 30, and the storage means 32 ′ in the power supply apparatus 300 ′ stores the characteristic information of the converter 30 ′.

  Further, the characteristic information stored in the storage means 32 becomes a signal data through the interface 33, and is further connected to the storage means 32 ′ through the interface 33 ′.

Further, the power supply apparatus 300 ′ generates driving information from the characteristic information from the interface 33 ′ and the characteristic information stored in the storage unit 32 ′.
And power supply device 300 'sets the characteristic of converter 30' based on driving | operation information.

  For example, the output voltage of the converter 30 ′ is set to be equal to the output voltage of the converter 30. Further, for example, the load current of the converter 30 ′ is set to be constant at a predetermined value.

  According to the configuration of the embodiment of FIG. 3, the utilization rate of the power supply device 300 and the power supply device 300 ′ can be increased. For example, when the output capacity of the power supply apparatus 300 is 100 W and the output capacity of the power supply apparatus 300 ′ is 50 W, the load 40 of 120 W can be operated according to the configuration of the embodiment of FIG.

  As described above, the present invention is not limited to the above-described embodiments, and includes many changes and modifications without departing from the essence thereof.

It is a block diagram which shows one Example of this invention. It is a block diagram which shows the other Example of this invention. It is a block diagram which shows the other Example of this invention.

Explanation of symbols

3 Main converter 4 Step down converter 5 Regulator 6 Control circuit 7,400 Load device 8, 300, 300 'Power supply device 13, 33, 43, 33' Interface 10, 12, 22, 32, 42, 32 'Storage means 11, 31, 41, 31 ′ arithmetic unit 20, 40 load 30, 30 ′ converter SW1, SW1 ′ switch Vi, Vi ′ input voltage Vo output voltage Io load current COM, COM ′ common potential GND ground potential Standby auxiliary output detect confirmation signal data signal

Claims (10)

In a power supply system comprising: a power supply device having a converter that converts an input voltage into an output; and a load device that has a load to which power is supplied from the converter and is detachable from the power supply device.
The load device includes first storage means for storing characteristic information of the load,
The power supply device includes an interface connected to the first storage means,
The power supply system, wherein the converter sets characteristics of the converter based on operation information based on the characteristic information.   The power supply system according to claim 1, wherein the converter is stopped when the interface and the first storage unit are disconnected.   2. The power supply system according to claim 1, wherein the power supply device includes a second storage unit that stores the characteristic information or the operation information and holds a value when the converter operates.   2. The power according to claim 1, wherein the power supply device includes an auxiliary output that supplies power to the first storage unit, and operates the converter based on a confirmation signal from the load device to the power supply device. Supply system. In a power supply system comprising: a power supply device having a converter that converts an input voltage into an output; and a load device that has a load to which power is supplied from the converter and is detachable from the power supply device.
The power supply device includes first storage means for storing converter characteristic information of the converter,
The load device includes second storage means for storing load characteristic information of the load,
The said converter sets the characteristic of the said converter based on the driving | operation information based on the said load characteristic information and the said converter characteristic information, The electric power supply system characterized by the above-mentioned. In a power supply system comprising: a power supply device having a converter that converts an input voltage into an output; and a load device that has a load to which power is supplied from the converter and is detachable from the power supply device.
The power supply device includes storage means for storing characteristic information of the converter,
The load is characterized in that a load characteristic is set based on operation information based on the characteristic information. A first power supply device having a first converter that converts a first input voltage into a first output, and a second converter that converts a second input voltage into a second output, and is detachable from the first power supply device A power supply system comprising a second power supply device,
The first power supply device includes storage means for storing characteristic information of the first converter,
The second power supply device sets the characteristic of the second converter based on operation information based on the characteristic information. In a power supply method of a power supply system, comprising: a power supply device including a converter that converts an input voltage into an output; and a load device that includes a load that is supplied with power from the converter and is detachable from the power supply device. ,
Communicating the characteristic information of the load from the load device to the power supply device;
The converter supplies power to the load based on operation information based on the characteristic information;
A power supply method comprising: In a power supply method of a power supply system, comprising: a power supply device including a converter that converts an input voltage into an output; and a load device that includes a load that is supplied with power from the converter and is detachable from the power supply device. ,
Communicating operation information based on characteristic information of the load from the load device to the power supply device;
The converter supplying power to the load based on the operation information;
A power supply method comprising: In a power supply method of a power supply system, comprising: a power supply device including a converter that converts an input voltage into an output; and a load device that includes a load that is supplied with power from the converter and is detachable from the power supply device. ,
Connecting the ground potential of the power supply device and the ground potential of the load device;
Connecting the output of the converter to the load and providing an auxiliary output from the power supply to the load;
The characteristics of the converter and the characteristics of the load are set based on operation information based on the load characteristic information and the converter characteristic information, and a step of communicating a confirmation signal from the load device to the power supply device,
The converter supplying power to the load;
A power supply method comprising:

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