JPH11299116A - Power supply adaptor, electronic apparatus and signal transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To permit the charging corresponding to the type of a secondary battery built in an electronic apparatus, by a method wherein an AC adaptor which has a plurality of voltage-current characteristics are connected to the electronic apparatus with two terminals for communication. SOLUTION: A power supply unit 11 supplies a power to a large power supply circuit 15 through a small power supply circuit 12 and a switching circuit 14. The small power supply circuit 12 and the large power supply circuit 15 are composed of constant voltage circuits and constant current circuits and output constant voltages and constant currents. A current detection circuit 13 detects the current outputted by the small power supply circuit 12. A signal receiving circuit 17 receives signals transmitted from a set. A charge control circuit 18 controls the small power supply circuit 12, the switching circuit 14 and the large power supply circuit 15 in accordance with the supplied signals. A power supply voltage supplied from an AC adaptor through terminals T3 and T5 is supplied to a secondary battery BT.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply adapter capable of transmitting a signal by connecting a power supply adapter and an electronic device with two terminals, that is, a + terminal and a-terminal. Related to transmission systems.

[0002]

2. Description of the Related Art Lithium ion batteries have attracted attention as secondary batteries for electronic equipment. Lithium-ion batteries are
Compared with the conventional secondary battery, there is an advantage that the duration can be extended and there is almost no memory effect. When the lithium-ion battery is charged, the electronic device is exchanged with a power supply adapter (hereinafter referred to as an AC adapter) and a microcomputer (microcomputer) of a set of electronic devices (hereinafter referred to as a set). It is determined whether or not the connected AC adapter is an AC adapter having a correct correspondence with the electronic device. This is because the secondary battery may be damaged if a voltage or current is supplied exceeding the rating of the secondary battery, for example, 4.2 V / 0.5 A, for example, if the battery is charged at 6 V / 1 A. .

[0003]

Therefore, in such a case, as shown in FIG. 15A, a charger 91 having an outlet that can be connected to a commercial power supply and a set 92 are connected to a positive terminal and a negative terminal.
The two terminals are connected to each other, and the secondary battery 93 incorporated in the set 92 is charged. This figure 1
In the example illustrated in FIG. 5A, when charging the secondary battery 93, the set 92 and the charger 91 are connected using the charger 91 having a correct correspondence with the characteristics of the secondary battery 93. If the charger 91 does not have the correct correspondence with the characteristics of the secondary battery 93,
The shape was changed so that the terminal part of the charger 91 and the terminal part of the set 92 did not match. Alternatively, the shape is changed so that the set 92 cannot be inserted into the charger 91.

[0004] However, it is difficult to completely prevent the connection between the charger and the set by changing the shape, and there has been a problem that the charger and the set that do not have a correct correspondence are connected.

As shown in FIG. 15B, an AC adapter 95 having an outlet connectable to a commercial power supply and a set 96 are connected to charge a secondary battery 97 incorporated in the set 96. It is. This secondary battery 97
The charger 98 for charging the battery was connected to the secondary battery 97 and was built in the set 96. Therefore, the secondary battery 97 has always been charged by the charger 98 having the correct correspondence.

[0006] However, there is a problem of increasing the size by providing a charger inside the set.

[0007] Accordingly, an object of the present invention is to connect two terminals, a + terminal and a-terminal, to connect an AC adapter having a plurality of voltage-current characteristics and an electric device to communicate with each other. It is an object of the present invention to provide a power supply adapter, an electronic device, and a signal transmission system that can perform charging according to the type of a secondary battery incorporated in a battery.

[0008]

According to a first aspect of the present invention, there is provided a power supply adapter which can be connected to an electronic device with two terminals, a low power mode for outputting low power, and a high power mode for outputting high power. A power supply unit capable of switching between, and a current detection unit that detects a current output from the power supply unit, and a signal reception unit that receives a signal transmitted from the electronic device,
A signal transmitting unit that transmits a signal to the electronic device, and when the current detected by the current detecting unit is equal to or less than a reference, the power supply unit operates in the low power mode, and the signal receiving unit operates.
A power supply comprising: control means for controlling switching to a high power mode based on a signal receiving means; and charging means having voltage-current characteristics for charging a secondary battery incorporated in an electronic device. Supply adapter.

According to a fifth aspect of the present invention, in an electronic device which can be connected to a power supply adapter with two terminals, signal receiving means for receiving a signal transmitted from the power supply adapter and transmitting a signal to the power supply adapter. Signal transmission means, control means for controlling based on a signal received by the signal reception means, switch means for cutting off power supplied from a power supply adapter, and a rechargeable secondary battery. Electronic equipment.

According to a ninth aspect of the present invention, there is provided a signal transmission system which is connected to an AC power supply and generates a predetermined DC power supply voltage, and a signal transmission system in which the power supply adapter and the electronic device are connected by two terminals. The power supply adapter includes a power supply unit capable of switching between a low power mode for outputting low power and a high power mode for outputting high power, a current detection unit for detecting a current output from the power unit, and an electronic device. A first signal receiving unit for receiving a signal to be transmitted, a first signal transmitting unit for transmitting a signal to an electronic device, and a power supply unit in a low power mode when a current detected by the current detecting unit is equal to or less than a reference. And operate the signal receiving means,
A first control unit that controls switching to a high power mode based on the signal receiving unit; and a charging unit that has a voltage-current characteristic for charging a secondary battery built in the electronic device. The device includes a second signal receiving means for receiving a signal transmitted from the power supply adapter, a second signal transmitting means for transmitting a signal to the power supply adapter, and a signal received by the second signal receiving means. Control based on the second
And a switch means for cutting off the power supplied from the power supply adapter, and a rechargeable secondary battery.

[0011] A charging device for connecting the AC adapter and the set with two terminals and charging a secondary battery built in the set is provided in the AC adapter. Further, the AC adapter is provided with a memory for storing information necessary for charging the secondary battery, for example, a charging capacity. From the set, a signal for reading the charging capacity is supplied to the AC adapter, and the charging capacity is read from the memory according to the signal, and the charging capacity is transmitted to the set as a signal. In the set,
Upon receiving the transmitted signal, the charging capacity is displayed. Then, the type of the secondary battery included in the set is transmitted as a signal from the set to the AC adapter. Upon receiving the signal, the AC adapter selects an AC adapter mode or a charging mode having a voltage-current characteristic matching the type of the secondary battery, and according to the selected mode, the small power supply circuit and the large power supply circuit Be operated. Also,
In the set, it is determined whether or not the types of the secondary batteries match, and if not, the set switch circuit SW is turned off.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows an overall configuration of an embodiment to which the present invention is applied. FIG. 1A shows a configuration in which a charger 1 having an outlet that can be connected to a commercial power supply and a secondary battery BT are connected by two terminals, a + terminal and a − terminal, and charge the secondary battery BT. . FIG. 1B shows an AC adapter 5 having an outlet connectable to a commercial power supply.
And the set 7 are connected, and the secondary battery BT incorporated in the set 7 is charged. This secondary battery B
A charger 6 for charging T is built in the AC adapter 5 and supplies voltage and current for charging the secondary battery BT of the set 7.

FIG. 2 shows a first embodiment of the present invention.
In the power supply unit 11, power is supplied to the large power supply circuit 15 via the small power supply circuit 12 and the switch circuit 14. The small power supply circuit 12 includes a constant voltage circuit and a constant current circuit, and outputs a constant voltage and constant current. The current detection circuit 13 detects the value of the current output from the low power supply circuit 12. The detected current value is supplied to the signal transmission circuit 16 and the charge control circuit 18. The high power supply circuit 15 includes a constant voltage circuit and a constant current circuit, and outputs a constant voltage and a constant current, similarly to the low power supply circuit 12. The output constant voltage / constant current has a value larger than the value output from the small power supply circuit 12.

A signal is transmitted to the set based on the current value from the current detection circuit 13. The signal receiving circuit 17 receives a signal transmitted from the set. The received signal is
It is supplied to the charge control circuit 18. In the charging control circuit 18, the small power supply circuit 12, the switch circuit 14, and the large power supply circuit 15 are controlled based on the current value from the current detection circuit 13 and the signal from the signal reception circuit 17. Here, as an example, a signal can be transmitted by using a clock of 5 V and 3 V between the AC adapter and the set and detecting the clock.

Voltage and current are supplied to the set via terminals T3 and T5. The voltage power supplied from the AC adapter is supplied to the secondary battery BT via the set switch circuit SW and charged. The signal receiving circuit 19 receives a signal transmitted from the AC adapter. The set switch circuit SW is turned on based on the received signal. In the signal transmission circuit 20, a signal is transmitted to the AC adapter. When the signal is transmitted, the set switch circuit SW
Is turned off. Terminals T4 and T6 are grounded.

In this embodiment, a charger for charging a secondary battery incorporated in the set or a circuit for performing a charging operation is provided inside the AC adapter. In addition, when a battery pack or a set containing a secondary battery is connected to an AC adapter via two terminals and communication is performed to perform charging (charging mode), charging control appropriate for the type of the secondary battery is performed. Done. Or, when not charging, that is, AC
When used as an adapter (AC adapter mode), control is performed according to the characteristics of the set. The charging mode and the AC adapter mode can be switched and used by communication between the AC adapter and the set.

In the charging mode, the voltage / current characteristics can be switched depending on the type of the battery. For example, nickel cadmium (Ni-C
d) When a battery and a nickel hydride (Ni-MH) battery are used, the voltage-current characteristic shown in a of FIG. 3A is output from the charger, and when a lithium ion (Li-ion) battery is used, The voltage-current characteristics shown in FIG. 3B are output from the charger. The voltage-current characteristics when charging the lithium ion battery are shown in FIG.
The voltage-current characteristics in the adapter mode are shown in FIG. In the case where the connected set has an incorrect correspondence, the charger is used as an operation-dedicated charger, so that safety can be ensured.

FIG. 4 shows a second embodiment of the present invention.
A low power supply circuit 21 and a current detection circuit 22 are inserted between terminals T1 and T3. Also, a large power supply circuit 23 is inserted in parallel with the small power supply circuit 21 and the current detection circuit 22. The small power supply circuit 21 includes a constant voltage circuit and a constant current circuit, and outputs a constant voltage and constant current. The current detection circuit 22 detects the value of the current output from the low power supply circuit 21. The detected current value is supplied to the charge control circuit 24. High power supply circuit 2
Reference numeral 3 is composed of a constant voltage circuit and a constant current circuit, like the small power supply circuit 21, and outputs a constant voltage and constant current. The output constant voltage / constant current has a value larger than the value output from the small power supply circuit 21. In the charging control circuit 24, the small power supply circuit 21 and the large power supply circuit 23 are controlled based on the supplied current value. The high power supply circuit 23 is also controlled by the stop circuit 25.

FIG. 5 shows a configuration example of the small power supply circuit and the large power supply circuit. Voltage power is supplied from the terminal 31 to the constant current circuit 32. When the constant current circuit 32 is used in a small power supply circuit, the value of the output constant current is small, and when used in a large power supply circuit, the value of the output constant current is large. . The constant voltage circuit 33 outputs a constant voltage.

As an example, a low power supply circuit outputs voltage-current characteristics as shown in FIG. 6A, and a high power supply circuit outputs voltage-current characteristics as shown in FIG. 6B. When I ₁ in FIG. 6 is detected by the current detection circuit becomes a low-power mode, operating the lower power supply circuit stops the operation of the higher power supply circuit. Also, when I _{2 in} FIG. 6 is detected by the current detection circuit, a high power mode is set, and both the low power supply circuit and the high power supply circuit are operated.

FIG. 7 shows a third embodiment of the present invention.
A low power supply circuit 41 and a current detection circuit 42 are inserted between terminals T1 and T3. Low power supply circuit 41
Then, a constant voltage / constant current is output, and the current detection circuit 42 detects a current value output from the small power supply circuit 41. The detected current value is supplied to the switch OFF detection circuit 4
5. A large power supply circuit 43 and a current detection circuit 44 are inserted in parallel with the small power supply circuit 41 and the current detection circuit 42. The high power supply circuit 43 outputs a constant voltage and a constant current, and the current detection circuit 44 detects a current value output from the high power supply circuit 43. The detected current value is supplied to the stop circuit 48.

In the switch OFF detection circuit 45, a large power supply circuit 43 is provided based on the current value from the current detection circuit 42.
Is supplied to the stop circuit 48. The signal transmitted from the set via the terminal T3 is received by the signal receiving circuit 46. Signal receiving circuit 46
Then, a signal is supplied to the stop circuit 48 or the charging mode operation circuit 49 in order to stop or operate the operation state of the high power supply circuit 43 from the received signal. In the signal transmission circuit 47, in order to transmit a signal from the AC adapter to the set, a signal for stopping the operation of the large power supply circuit 43 is supplied to the stop circuit 48, and a signal transmitted through the terminals T3 and T5. Is transmitted.

In the stop circuit 48, the current detection circuit 44
, The signal from the switch OFF detection circuit 45, the signal from the signal reception circuit 46, and the signal transmission circuit 4
7, a signal for stopping the operation of the high power supply circuit 43 is supplied to the high power supply circuit 43. In the charging mode operation circuit 49, based on the signal from the signal receiving circuit 46, the secondary battery BT built in the set
The small power supply circuit 41 and the large power supply circuit 43 are operated in the charge mode of the voltage-current characteristic corresponding to the type of the power supply. The terminals T4 and T6 are connected, and the terminals T2 and T4
And T6 are grounded.

A set switch circuit SW is inserted between the terminal T5 and the secondary battery BT. The signal transmitted from the AC adapter is transmitted to the signal receiving circuit 51 via the terminal T5.
Received at. In the signal receiving circuit 51, the received signal is supplied to the switch control circuit 52 and the control circuit 53. The switch control circuit 52 controls the on / off operation of the set switch circuit SW and the operation of the signal transmission circuit 56 based on the supplied signal. The control circuit 53 performs an operation according to the supplied signal. The temperature detection circuit 54 detects the temperature of the secondary battery BT, and supplies the detected temperature to a signal transmission circuit 56. The voltage detection circuit 55 detects the terminal voltage of the secondary battery BT, and supplies the detected terminal voltage to the signal transmission circuit 56. In the signal transmission circuit 56, the signal from the switch control circuit 52, the temperature from the temperature detection circuit 54, and the voltage detection circuit 5
A signal is transmitted from the set to the AC adapter via terminals T5 and T3 so as to operate according to the state of the set based on the terminal voltage from the terminal 5.

The operation of this embodiment will be described. First, A
The C adapter operates in a low power mode in which the low power supply circuit 41 is operated and the high power supply circuit 43 is stopped, and the set switch turns off the set switch circuit SW.
If there is no signal from the AC adapter even if there is a power input, the set switch circuit SW remains off. When transmitting a signal from the set to the AC adapter, in the set, the set switch circuit SW is turned off, it is confirmed that the mode is switched to the low power mode, and the signal is transmitted. When the set switch circuit SW is turned off from the AC adapter, the power input is stopped, a signal is transmitted from the set, and the mode is set to the low power mode. Alternatively, a signal for turning off the set switch circuit SW is transmitted from the AC adapter to the set. In this way, the AC adapter is in the low power mode and can transmit signals.

FIG. 8 shows a flowchart of an example of this embodiment. In step S1, input power is turned on to the AC adapter. In step S2, the operation is performed in the low power mode in which the low power supply circuit is operated and the high power supply circuit is stopped. In step S3, a signal transmitted from the set is received. In step S4, it is determined whether or not a signal has been received. If it is determined that a signal has been received, control proceeds to step S5. If it is determined that no signal has been received, control returns to step S3. . Step S5
Then, the received signal is analyzed.

In step S6, the state of the set is determined from the analyzed signal, the output is determined, and if it is determined that the voltage-current characteristic for the charging mode is to be output, the control proceeds to step S7. When it is determined that the voltage / current characteristic to be in the AC adapter mode is output, the control is shifted to step S12, and the secondary battery BT included in the set is out of an appropriate temperature range or in an overcharged state. Is determined, the control moves to step S13.

In step S7, the voltage-current characteristic in the charging mode is selected, and the control moves to step S8. In step S12, the voltage / current characteristic in the AC adapter mode is selected, and the control moves to step S8. In step S8,
The operation of the small power supply circuit and the operation of the large power supply circuit are controlled according to the charging mode or the AC adapter mode. In step S9, the small power supply circuit and the large power supply circuit are operated according to the control. In step S10, the off state of the set switch circuit SW is detected.
In step S11, it is determined whether or not the set switch circuit is in the off state. If it is determined that the set switch circuit is in the off state, control returns to step S2. If it is determined that the set switch circuit is in the on state, control returns to step S10. .

In step S13, since the secondary battery BT included in the set is out of an appropriate temperature range or in an overcharged state, a voltage-current characteristic that avoids that state is selected. In step S14, the display unit indicates that the secondary battery is currently out of the appropriate temperature range or in an overcharged state. This step S1
After the process of step 3, the control is shifted to step S14, but the control may be shifted to step S2 in parallel with step S14. This is because the state of the secondary battery BT is out of an appropriate temperature range or is in an overcharged state, so that the secondary battery BT is immediately operated in the low power mode.

In step S2, when the AC adapter operates in the low power mode, the set proceeds to step S21.
To S28 are performed. In step S21, when it is confirmed that the AC adapter is operating in the low power mode, a signal is transmitted from the set to the AC adapter. In step S22, what kind of A
It is determined whether output from the C adapter is required,
If it is determined that the mode is the charging mode, the control proceeds to step S23, and if it is determined that the mode is the AC adapter mode,
The control proceeds to step S26, and when it is determined that the temperature is out of the appropriate temperature range for the secondary battery BT or that the secondary battery BT is in the overcharged state, the control proceeds to step S27.

In step S23, a signal for setting the output characteristics of the AC adapter to the charging mode is transmitted from the set to the AC adapter. In step S26, a signal for setting the output characteristic of the AC adapter to the AC adapter mode is transmitted from the set to the AC adapter. Step S27
In the case, when the temperature of the secondary battery BT is out of the predetermined range or when the battery is overcharged, the fact is notified to the AC adapter and a signal for stopping the output is transmitted.
The signals transmitted from these steps S23, S26 and S27 are received in step S3.

In step S24, an ON signal for turning on the set switch circuit SW is supplied. In step S28, an off signal for turning off the set switch circuit SW is supplied. In step S25, the set switch circuit SW is turned on / off according to the supplied signal.

FIG. 9 shows a flowchart of an example of this embodiment. FIG. 9 shows an example of the operation in the charging mode and the AC adapter mode. In step S31, AC
An operation of transmitting a signal from the adapter is performed. In step S32, an OFF signal for turning off the set switch circuit is transmitted. In step S33, AC
Power output from the adapter is suspended. Step S
At 34, it is operated in the low power mode. Step S35
In, voltage or current is detected. In step S36, it is determined whether or not the set switch circuit SW is in the off state based on the detected voltage or current, and if it is determined that the set switch circuit SW is in the off state, step S3 is performed.
When control is transferred to step 7 and it is determined that the switch is on, step S
Control returns to.

In step S37, a signal is transmitted.
In step S38, an ON signal for turning on the set switch circuit is transmitted from the AC adapter to the set. In step S39, the AC adapter is operated in the large power mode in which the small power supply circuit and the large power supply circuit are operated. In step S40, a current is detected.
In step S41, it is determined whether or not the detected current is equal to or greater than the reference current. If it is determined that the detected current is equal to or greater than the reference current, the process returns to step S40. The control moves to step S42.
In Step S42, after a predetermined time of Δt, Step S
At 43, the mode is switched to the low power mode.

After the above-described control in step S32, the process proceeds to step S33.
May be controlled. In step S44,
A stop signal is transmitted from the set, and the output of the AC adapter is stopped. Further, the control in step S42 may be omitted. That is, control may be shifted from step S41 to S43.

FIG. 10 shows a fourth embodiment of the present invention. FIG. 10 shows a block diagram of an example of the set. The temperature detection circuit 61 detects the temperature of the secondary battery BT. The detected temperature is supplied to a stop signal circuit 64 and a signal transmission circuit 65. Charge capacity reading circuit 6
In No. 2, since the charging capacity of the secondary battery BT is stored in the memory of the AC adapter, in order to read out the stored charging capacity, the stop signal circuit 64 and the signal transmission circuit 6
5 and a signal receiving circuit 66. In the battery type section 63, the type of the secondary battery BT included in the set is supplied to the stop signal circuit 64, the signal transmission circuit 65, and the comparison section 69. As an example of the type of the secondary battery BT, a nickel cadmium (Ni-Cd) battery, a nickel hydride (Ni-M
H) A battery or a lithium ion (Li-ion) battery is used.

The stop signal circuit 64 includes the temperature detection circuit 6
The set switch circuit SW is turned off based on the temperature from 1, the signal from the charge capacity reading circuit 62, the signal from the battery type unit 63, and the signal from the comparison unit 69.
In the signal transmission circuit 65, the temperature from the temperature detection circuit 61,
Signal from charge capacity reading circuit 62 and battery type section 63
The signal is transmitted to the AC adapter based on the signal from. The signal receiving circuit 66 receives a signal transmitted from the AC adapter. The received signal is supplied to the charge capacity signal circuit 67 and the battery type signal 68. From the AC adapter, for example, the charge capacity of the secondary battery, whether or not the secondary battery BT included in the set has the voltage-current characteristic, and the like are transmitted as signals. The charge capacity signal circuit 67 determines the charge capacity from the received signal. In the battery type signal circuit 68, A
The type of battery corresponding to the voltage-current characteristics of the C adapter is determined. The comparing unit 69 determines whether or not the type of the secondary battery BT supplied from the battery type unit 63 matches the type of the battery supplied from the battery type signal circuit 68. As a result of the determination, if the battery types do not match, in order to turn off the set switch circuit SW,
A signal is supplied from the comparator 69 to the stop signal circuit 64.

FIG. 11 shows a flowchart of an example of this embodiment. In step S51, the set switch circuit SW is turned on. In step S52, a signal is transmitted from the set to the AC adapter. In step S53, the set switch circuit SW is turned off. In step S54, it is detected whether or not the AC adapter is operating in the low power mode in which the small power supply circuit is operated and the large power supply circuit is stopped. In step S55, it is determined whether or not the detected state of the AC adapter is in the low power mode.
When the control is shifted to 56 and it is determined that the mode is not the low power mode, the control is shifted to step S62. In step S62, after a predetermined time Δt, the control returns to step S53, and the set switch circuit SW is turned off.

In step S56, a signal is transmitted.
In step S57, the transmitted signal is confirmed. In step S58, the presence or absence of the transmitted signal is determined,
When it is determined that there is no signal, the control returns to step S53, and when it is determined that there is a signal, the control proceeds to step S59. In step S59, after a predetermined time Δt, the control moves to step S60. In step S60, a signal is received. In step S61, the set is controlled based on the received signal, and the control returns to step S51.

In step S55, if it is determined that the mode is not the low power mode, the control shifts to step S62. However, the control may shift to step S54. In step S58, when it is determined that the transmitted signal is present, the control is shifted to step S59. However, the control may be shifted to step S60 without performing the control in step S59. good.

FIG. 12 shows a fifth embodiment of the present invention. FIG. 12 shows a block diagram of an example of the AC adapter. A small power supply circuit 7 is connected between terminals T1 and T3.
1 and the current detection circuit 72 are inserted. Also, a large power supply circuit 73 is inserted in parallel with the small power supply circuit 71 and the current detection circuit 72. In the small power supply circuit 71,
A constant voltage / constant current as indicated by a in FIG. 13 is output, and the high power supply circuit 73 outputs a constant voltage / constant current as indicated by b in FIG. The current detection circuit 72 detects a current output from the low power supply circuit 71. The detected current value is supplied to the switch OFF detection circuit 74.

In the switch OFF detection circuit 74, a signal is supplied to the stop circuit 75 based on the supplied current value so as to turn off the large power supply circuit 73. In the stop circuit 75, based on a signal from the switch OFF detection circuit 74, control is performed so that the large power supply circuit 73 is turned off. As an example, when a current equal to or less than the current c shown in FIG. 13 is detected, the operation of the large power supply circuit 73 is stopped in order to set the small power mode.

In the receiving circuit 76, a signal transmitted from the set via the terminal T3 is received. The received signal is supplied to the switching circuit 77 and the memory 78.
The memory 78 stores, for example, the charge capacity of the secondary battery BT included in the set from the received signal.
The stored charging capacity is supplied to the switching circuit 77 and the signal transmission circuit 79. When the signal transmission circuit 79 transmits a signal indicating that the charging capacity is to be known from the set,
The charge capacity read from the memory 78 is transmitted via the terminal T3. The switching circuit 77 switches so as to select any one of the AC adapter mode 82, the A battery charging mode 83, and the B battery charging mode 84 based on the signal from the receiving circuit 76 and the signal from the memory 78. Switching of the circuit 80 is controlled. Control circuit 81
Controls the small power supply circuit 71 and the large power supply circuit 73 according to the voltage-current characteristics of the mode selected by the switching circuit 77.

FIG. 14 shows a flowchart of an example of this embodiment. In step S71, a current is detected.
In step S72, it is determined from the detected current whether the set switch circuit SW is in the off state, and if it is determined that the set switch circuit SW is in the off state, the process proceeds to step S72.
The control shifts to 73, and if it is determined that it is in the ON state, the control returns to step S71. In step S73, the AC adapter is operated in the low power mode in which the low power supply circuit is operated and the high power supply circuit is stopped. Step S7
At 4, a signal transmitted from the set is received. In step S75, the received signal is analyzed.

In step S76, it is determined whether or not the charging mode is determined as a result of the analysis. If it is determined that the charging mode is set, the control proceeds to step S77. If it is determined that the charging mode is set, the process proceeds to step S82. The control moves to. In step S82, the operation of the AC adapter is performed according to the voltage-current characteristics in the AC adapter mode. In step S77, the secondary battery BT built in the set
It is determined whether the battery is an A battery or a B battery. If it is determined that the battery is the A battery, the control proceeds to step S83. If the battery is determined to be the B battery, the control proceeds to step S78. In step S83, the operation of the AC adapter is performed according to the voltage-current characteristics in the A battery mode. In step S77, the operation of the AC adapter is performed according to the voltage-current characteristics in the B battery mode. That is, in steps S76 and S77, the voltage-current characteristics according to the type of the secondary battery BT included in the set are selected.

In step S79, the switching circuit is switched so that the selected voltage-current characteristic is obtained. In step S80, the voltage-current characteristics supplied via the switching circuit are supplied to the control circuit. In step S81, the operation is performed in the high power mode in which the small power supply circuit and the large power supply circuit are operated according to the voltage-current characteristics supplied to the control circuit, and the control returns to step S71.

After the control in step S75, the control is shifted to step S76. However, the control may be shifted in parallel to steps S91, S92 and S93 shown by the dotted lines in FIG. In step S91, a signal for reading the stored charge capacity is received from the memory that stores the charge capacity of the secondary battery BT included in the set. In step S92, the charge capacity of the secondary battery BT is read from the memory. Step S93
Then, the read charging capacity is transmitted as a signal from the AC adapter to the set, and the control returns to step S74.

[0048]

According to the present invention, the AC adapter and the set are connected by two terminals to transmit a signal,
Since the AC adapter can be controlled from the set,
The degree of safety can be increased, and a plurality of types of batteries can be charged. Also, even when used as a dedicated charger, the degree of safety can be increased.

According to the present invention, the range of use can be increased by switching between the AC adapter mode and the charging mode.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing a schematic configuration of the present invention.

FIG. 2 is a block diagram showing a first embodiment to which the present invention is applied.

FIG. 3 is an example of a voltage-current characteristic for explaining the present invention.

FIG. 4 is a block diagram showing a second embodiment to which the present invention is applied.

FIG. 5 is a block diagram of an example of a small power supply and a large power supply to which the present invention is applied.

FIG. 6 is an example of a voltage-current characteristic for explaining the present invention.

FIG. 7 is a block diagram showing a third embodiment to which the present invention is applied.

FIG. 8 is a flowchart of an example of signal transmission to which the present invention is applied.

FIG. 9 is a flowchart of an example of signal transmission to which the present invention is applied.

FIG. 10 is a block diagram showing a fourth embodiment to which the present invention is applied.

FIG. 11 is a flowchart of an example of signal transmission to which the present invention is applied.

FIG. 12 is a block diagram showing a fifth embodiment to which the present invention is applied.

FIG. 13 is an example of a voltage-current characteristic for explaining the present invention.

FIG. 14 is a flowchart of an example of signal transmission to which the present invention is applied.

FIG. 15 is a schematic diagram of a conventional AC adapter and electronic equipment.

[Explanation of symbols]

11: power supply unit, 12: low power supply circuit, 13
..Current detection circuit, 14 ... Switch circuit, 15 ...
.High-power power supply circuit, 16, 20, ... signal transmission circuit, 1
7, 19: signal receiving circuit, 18: charge control circuit, SW: set switch circuit, BT: secondary battery

Claims (13)

[Claims] 1. A power supply adapter that can be connected to an electronic device with two terminals, a power supply unit capable of switching between a low power mode for outputting low power and a high power mode for outputting high power, and Current detecting means for detecting the output current; signal receiving means for receiving a signal transmitted from the electronic device; signal transmitting means for transmitting a signal to the electronic device; and the current detected by the current detecting means Is less than or equal to a reference, the power supply unit is operated in the low power mode, the signal receiving means is operated, and based on the signal receiving means, control means for controlling switching to the high power mode, A power supply adapter comprising: charging means having a voltage-current characteristic for charging a secondary battery built in a device. 2. The rechargeable battery according to claim 1, wherein the charging unit has a plurality of voltage-current characteristics, and based on a signal transmitted from the electronic device, selects one of the plurality of voltage-current characteristics from the plurality of voltage-current characteristics. A power supply adapter characterized in that corresponding voltage-current characteristics are selected. 3. The electronic device according to claim 1, further comprising a memory for storing information necessary for charging a secondary battery built in the electronic device, wherein the information stored in the memory is the signal A power supply adapter characterized in that transmission is performed from the transmission means to the electronic device. 4. The power supply adapter according to claim 1, further comprising stop means for stopping the operation in the low power mode and / or the high power mode. 5. An electronic device connectable to a power supply adapter with two terminals, a signal receiving means for receiving a signal transmitted from the power supply adapter, a signal transmitting means for transmitting a signal to the power supply adapter, An electronic device comprising: control means for controlling based on the signal received by the signal receiving means; switch means for cutting off power supplied from the power supply adapter; and a rechargeable secondary battery. . 6. The power supply adapter according to claim 5, wherein the temperature of the secondary battery is detected, and when the temperature is out of a predetermined temperature range, a signal is transmitted to the power supply adapter by the signal transmission means. An electronic device, wherein the electronic device is turned off. 7. The signal transmission means according to claim 5, wherein the signal transmission means transmits a signal for reading information necessary for charging the secondary battery stored in a memory of the power supply adapter. Electronic equipment characterized by the above. 8. The electronic apparatus according to claim 5, wherein the signal transmitting unit transmits the type of the secondary battery as a signal. 9. A power supply adapter connected to an AC power supply for generating a predetermined DC power supply voltage, and a signal transmission system in which the power supply adapter and the electronic device are connected by two terminals. A power supply unit capable of switching between a low power mode for outputting power and a high power mode for outputting high power; a current detection unit for detecting a current output from the power supply unit; and a signal transmitted from the electronic device. First signal receiving means for receiving; first signal transmitting means for transmitting a signal to the electronic device; and when the current detected by the current detecting means is equal to or less than a reference, the power supply section is set to a low power mode. Operating the signal receiving means, and controlling to switch to the high power mode based on the signal receiving means.
Control means, and charging means having voltage-current characteristics for charging a secondary battery built in the electronic device, wherein the electronic device receives a signal transmitted from the power supply adapter. 2 signal receiving means, second signal transmitting means for transmitting a signal to the power supply adapter, second control means for controlling based on the signal received by the second signal receiving means, A signal transmission system comprising: switch means for disconnecting power supplied from a power supply adapter; and the rechargeable secondary battery. 10. The method according to claim 9, wherein the charging unit has a plurality of voltage-current characteristics, and the plurality of voltage and current characteristics are determined based on a type of the secondary battery transmitted from the second signal transmission unit. A signal transmission system, wherein a voltage-current characteristic corresponding to the secondary battery is selected from current characteristics. 11. The signal transmission system according to claim 9, further comprising stop means for stopping the operation in the low power mode and / or the high power mode. 12. The power supply adapter according to claim 9, wherein the power supply adapter has a memory for storing information necessary for charging a secondary battery built in the electronic device, and the second signal transmission means is A signal transmission system for transmitting a signal for reading information necessary for charging the secondary battery stored in the memory. 13. The switch according to claim 9, wherein the temperature of the power supply section is detected, and when the temperature is out of a predetermined temperature range, a signal is transmitted to the power supply adapter by the second signal transmitting means. A signal transmission system wherein the means is turned off.