JP3507764B2 - Electrical equipment - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention comprises a main body and a separate body detachable from the main body, which is separate from the primary side coupling circuit provided in the main body when the separate body is attached to the main body. The present invention relates to an electric device that is electromagnetically coupled with a provided secondary side coupling circuit.

[0002]

2. Description of the Related Art A main body and a separate body detachable from the main body, a primary side coupling circuit provided in the main body and a secondary side provided in a separate body when the separate body is attached to the main body. There are electric devices that are electromagnetically coupled to a coupling circuit. Examples of such electric devices are a set of a mobile phone and its charger (the main body of the charger is a separate body of the cordless phone), and the refrigerator has no contacts between the main body and the door because the doors are double-opened. There is one that supplies power from the main body to the door.

In these electric devices, when a foreign substance such as a metal is mixed between the primary side coupling circuit on the main body side and the secondary side coupling circuit on the separate side, a current flows through the foreign substance to generate heat, and the device or the user. There is a risk of damage to. In order to avoid such a risk, it is determined whether foreign matter is mixed based on the current value of the primary side coupling circuit.If it is determined that foreign matter is mixed in, the main body side It was designed to cut off the power supply to the coupling circuit.

[0004]

Specifically, when the current value of the primary side coupling circuit exceeds a threshold value, it is determined that foreign matter is mixed. The threshold value is set to be larger than the theoretically required current limit value in consideration of the fluctuation of the above, the fluctuation of the installation environment of the device, and the like. For example, when power is supplied with a voltage of 10 [V] and a current of 100 [mA], the threshold value is set to about 130 [mA].

Therefore, when the consumption current slightly increases due to the inclusion of foreign matter, the inclusion of foreign matter cannot be detected. Therefore, there is still a risk of damaging the device or the user due to the heat generation.

Therefore, according to the present invention, the main body comprises a separate body which is detachable from the main body, and when the separate body is attached to the main body, it is provided separately from the primary side coupling circuit provided in the main body. In an electric device in which the secondary side coupling circuit is electromagnetically coupled, even if a foreign matter such as a metal is mixed between the primary side coupling circuit and the secondary side coupling circuit, the foreign matter generates heat and becomes high temperature. It is an object of the present invention to provide an electric device that suppresses the above and improves safety.

[0007]

In order to achieve the above object, the present invention comprises a main body and a separate body which is detachable from the main body, and is provided on the main body when the separate body is attached to the main body. In an electric device in which the primary side coupling circuit and the secondary side coupling circuit provided separately are electromagnetically coupled, and the load of the secondary side coupling circuit can take a plurality of states, the primary side coupling circuit A current detection unit that detects a current value, a storage unit that stores in advance a reference current value of the primary side coupling circuit and a current limit value of the primary side coupling circuit, and a current value that is actually measured by the current detection unit. Correction value calculating means for calculating a difference value with the reference current value, and overcurrent detection for detecting an overcurrent of the primary side coupling circuit with a value obtained by adding the current limit value and the difference value as a threshold value. Means and
When the overcurrent is detected, the power supply control means for cutting off the power supply to the primary side coupling circuit is provided, and the calculation by the correction value calculation means is performed every time the load state of the separate body is changed. The difference value is updated.

With this configuration, the threshold value for overcurrent detection is corrected in accordance with the actual current value, and it becomes possible to perform highly accurate overcurrent detection by absorbing component variations and environmental variations. Moreover, since the threshold value for overcurrent detection is updated every time the load state changes, it becomes possible to perform highly accurate overcurrent detection even when the load state changes. By correcting the current limit value according to the temperature around the primary side coupling circuit, it is possible to further absorb the environmental variation and perform highly accurate overcurrent detection.

Further, according to the present invention, the main body and a separate body detachable from the main body are provided, and when the separate body is attached to the main body, the primary side coupling circuit provided in the main body is provided as a separate body. In an electric device in which the secondary side coupling circuit is electromagnetically coupled and the load of the secondary side coupling circuit can take a plurality of states, current detection means for detecting a current value of the primary side coupling circuit, and the load. Storage means for storing in advance the current limit value of the primary side coupling circuit and the reference current value of the primary side coupling circuit in the state where the load is at a minimum, according to the state of Temperature detection means for detecting the temperature of, and the load of the secondary side coupling circuit is set to the minimum,
First overcurrent detection means for detecting an overcurrent of the primary side coupling circuit with a current limit value in the state of a minimum load as a threshold value, and the overcurrent is not detected by the first overcurrent detection means. Sometimes, the correction value calculating means for calculating the difference value between the current value actually measured by the current detecting means and the reference current value, and the load of the secondary side coupling circuit are not the minimum, depending on the state of the load. Second overcurrent detection means for detecting an overcurrent of the primary side coupling circuit, using a value obtained by adding the current limit value of the primary side coupling circuit and the difference value as a threshold value; And a power supply control means for shutting off power supply to the primary side coupling circuit when an overcurrent is detected by the second overcurrent detection means, and according to the temperature detected by the temperature detection means.
The current limit value previously stored by the storage means.
The first or second overcurrent detection means after correcting
Is configured to detect an overcurrent .

With this configuration, even if the load of the secondary side coupling circuit can be in a plurality of states, the threshold value for overcurrent detection is corrected for each load according to the actual current value, so that the parts are It becomes possible to detect the overcurrent detection with high accuracy by absorbing the variation and the environmental variation. In addition, since the current limit value is corrected according to the temperature around the primary side coupling circuit, it is possible to further absorb environmental variations and perform highly accurate overcurrent detection.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a mobile phone charger 100 and a mobile phone 200 according to a first embodiment of the present invention.
It is a block diagram of. The power supply 11 includes a current detection circuit 14
The power is supplied to the control circuit 15 including a microcomputer and the power cutoff circuit 13. Power cutoff circuit 13
Is the primary side coupling circuit 1 according to an instruction from the control circuit 15.
The power supply to 2 is cut off. The current detection circuit 14 detects the current value of the primary side coupling circuit 12 and outputs it to the control circuit 15. The control circuit 15 detects an overcurrent of the primary side coupling circuit 12 based on the current detected by the current detection circuit 14 and cuts off the power feeding to the primary side coupling circuit 12 by the power feeding cutoff circuit 13 and also performs the primary side coupling. The operation of the circuit 12 is stopped.

When the mobile phone 200 is mounted on the charger 100, a coil (not shown in FIG. 1) in the primary side coupling circuit 12 of the charger 100 and a secondary side coupling circuit 21 of the mobile phone 200 are provided. A coil (not shown in FIG. 1) is electromagnetically coupled. As a result, power is supplied from the secondary side coupling circuit 21 to the load 20, and the battery of the mobile phone 200 is charged.

The control circuit 15 is provided with a memory 15A which stores a reference current value and a current limit value in advance.

A detailed structure of the current detection circuit 14 is shown in FIG. The power supply voltage 14.5 [V] is applied as an operating voltage to the primary-side non-contact power supply unit 122 that drives the coil 121 of the primary-side coupling circuit 12 via the power supply cutoff circuit 13. The primary-side non-contact power supply unit 122 has a control terminal CTL and operates when the signal input to the control terminal CTL is at high level, while it operates when the signal is at low level. There is no such thing.

When the mobile phone 200 is attached to the charger 100, the coil 121 of the primary side coupling circuit 12 is driven to cause electromagnetic induction and the mobile phone 200.
Power is generated in the coil 211 of the secondary side coupling circuit 21 of
From this power, the secondary side non-contact power supply unit 212
A voltage of [V] is generated and supplied to the load 20.

The power supply cutoff circuit 13 receives the power supply control signal S1 output from the control circuit 15, and cuts off the supply of the power supply voltage to the primary side coupling circuit 12 based on the power supply control signal S1. Has become.

ON / OFF output from the control circuit 15
The control signal S2 is input to the base of the NPN type transistor T1 via the resistor R1. A resistor R2 is connected between the base and emitter of the transistor T1. The emitter of the transistor T1 is grounded. The collector of the transistor T1 is connected to the power supply voltage (5
[V]) and a control terminal C of the primary side non-contact power supply unit 122 via a resistor R4.
It is connected to TL. A capacitor C1 is connected between the emitter and collector of the transistor T1. A capacitor C2 is connected between the terminal for inputting the power supply voltage (5 [V]) and the terminal connected to the ground.

As a result, when the ON / OFF control signal S2 is at a low level, the transistor T1 is OFF, so that the signal input to the control terminal CTL of the primary side non-contact power supply unit 122 is at a high level,
The primary-side non-contact power supply unit 122 operates. on the other hand,
When the ON / OFF control signal S2 is at high level,
Since the transistor T1 is ON, the signal input to the control terminal CTL of the primary side non-contact power supply unit 122 is low level, and the primary side non-contact power supply unit 1
22 does not operate.

The ground terminal GND of the primary side non-contact power supply unit 122 is grounded via a resistor R5. The non-grounded side of the resistor R5 is connected to the non-inverting input terminal (+) of the operational amplifier OP1 via the resistor R6. An electric field capacitor C11 is connected to both ends of the resistor R5. The connection point between the resistor R6 and the non-inverting input terminal (+) of the operational amplifier OP1 is grounded via the capacitor C3.

The inverting input terminal (-) of the operational amplifier OP1 is grounded via the resistor R7 and connected to the output terminal of the operational amplifier OP1 via the resistor R8.
The output terminal of the operational amplifier OP1 is connected to the non-inverting input terminal (+) of the operational amplifier OP2 via the resistor R9.
The inverting input terminal (-) of the operational amplifier OP2 is grounded via the resistor R10 and is connected to the output terminal of the operational amplifier OP2 via the resistor R11. The output terminal of the operational amplifier OP2 is grounded via the resistor R12.

As a result, the signal output from the operational amplifier OP2 is a current detection signal obtained by converting the current of the primary side coupling circuit 12 into a voltage, and this current detection signal is controlled via the resistor R13. It is input to the circuit 15. The control circuit 15 recognizes the current value of the primary side coupling circuit 12 by A / D converting the input current detection signal S3 and processing it.

The operation of the control circuit 15 will be described with reference to the flowchart shown in FIG. When the power is turned on, the current value of the primary side coupling circuit 12 is taken in and the taken current value I
Difference value between the reference current value i stored in advance in the _R memory 15A .DELTA.i the (Δi = I _R -i) is calculated (step #
10). Next, the sum of the current limit value I stored in advance in the memory 15A and the difference value Δi obtained in step # 10 is stored as the threshold value I _th (step # 20).

Next, it is determined whether or not the state of the load 20 of the mobile phone 200 has changed (step # 25). If the state of the load 20 has not changed (N in step # 25), the process proceeds to step # 30. On the other hand, when the state of the load 20 is changed by performing an operation such as switching to the call state by receiving a call during charging (Y in step # 25), the process proceeds to step # 10, and the difference value Δi is calculated again. To do. The change in the state of the load 20 is detected by the control circuit 15 from the change in the current value of the primary side coupling circuit 12 based on the current detection signal S3. It should be noted that the control circuit 1 on the charger 100 side is added with a communication function like the refrigerator of the second embodiment described later.
Load 20 of mobile phone 200 based on the signal received by
It may be configured to recognize the state of.

Next, it is judged whether or not the current value I _R of the primary side coupling circuit 12 is larger than the threshold value I _th (step # 3).
0). If the current value I _R of the primary side coupling circuit 12 is larger than the threshold value I _th (Y in step # 30), it is determined that the current is an overcurrent, and the primary side coupling circuit 12 is notified to the power feeding cutoff circuit 13 by the power feeding control signal S1. Power is cut off and ON
The operation of the primary side coupling circuit 12 is stopped by the / OFF control signal S2 (step # 40). It should be noted that, when power supply to the primary side coupling circuit 12 is cut off, it is desirable to be configured to give a warning to that effect.

When a predetermined time has elapsed after step # 40 (Y in step # 50), power supply to the non-contact power supply unit 122 is restarted by the power supply control signal S1 (step # 60), and then ON / OFF. The operation of the contactless power supply unit 122 is restarted by the control signal S2 (step # 70). After step # 70, the above step #
Move to 25.

On the other hand, as a result of the determination in step # 30, if the current value I _R of the primary side coupling circuit 12 is not larger than the threshold value I _th (N in step # 30), it is determined whether the full charge signal is input. It is determined (step # 80). It should be noted that the full charge signal indicates the mobile phone 200 attached to the charger 100.
When the battery is fully charged, it is input to the control circuit 15.

If the full charge signal is not input (N in step # 80), the process proceeds to step # 25 described above,
On the other hand, if the full charge signal is input (step # 80
Y) of the primary side coupling circuit 1 with the ON / OFF control signal S2
The operation of No. 2 is stopped (step # 90). After that, when the full charge signal is released (Y in step # 100), the process proceeds to step # 70 described above.

With the above configuration, the threshold value for overcurrent detection is corrected according to the actual current value, and the threshold value for overcurrent detection is updated every time the load state is changed. Highly accurate overcurrent detection can be performed by absorbing environmental variations. This makes it possible to detect even a minute increase in current due to foreign matter such as metal mixed in between the primary side coupling circuit and the secondary side coupling circuit. As a result, when foreign matter is mixed in, the power supply to the primary side coupling circuit is cut off, whereby heat generation of foreign matter can be prevented and safety is improved.

FIG. 4 is a block diagram of the refrigerator according to the second embodiment of the present invention. The refrigerator main body 300 includes a power source 11, a primary side coupling circuit 12, a power supply cutoff circuit 13, and a current detection circuit 1.
4, a control circuit 15 including a microcomputer, an infrared communication circuit 16, and a temperature sensor 17. The temperature sensor 17 is provided around the primary side coupling circuit 12. The ambient temperature of the primary side coupling circuit 12 detected by the temperature sensor 17 is input to the control circuit 15.

The door 400 has a structure such that a contact cannot be secured with the main body 300 (for example, in the case of a double door), and is composed of a secondary side coupling circuit 21, a liquid crystal panel 22, an infrared communication circuit 23, and a microcomputer. It consists of a control circuit 24. The parts having the same functions as those in the first embodiment are designated by the same reference numerals and the description thereof will be omitted.

FIGS. 5 and 6 are circuit diagrams of the refrigerator of the second embodiment showing in detail the configurations of the current detection circuit 14 and the infrared communication circuits 16 and 23. The infrared communication circuits 16 and 23 each include a transmission / reception buffer P1 and a transmission / reception unit P2.

First, the structure of the transmission / reception buffer P1 will be described. The transmission signal S4 output from the control circuit 15 has a resistance R
It is given to the base of the NPN type transistor T2 via 14. A resistor R15 is connected between the base and emitter of the transistor T2. The emitter of the transistor T2 is grounded. The collector of the transistor T2 is connected to the power supply voltage (5 [V]) via the resistor R16. The collector voltage of the transistor T2 is output to the output terminal OUT via the resistor R17.

The signal received by the transmitting / receiving unit P2 is
It is input from the input terminal IN to the base of the PNP type transistor T3 via the resistor R18. The base of the transistor T3 has a resistor R19 and a capacitor C connected in parallel.
4 and the power supply voltage (5 [V]).
The emitter of the transistor T3 is connected to the power supply voltage (5 [V]). The collector of the transistor T3 is a resistor R
It is grounded via 20. The collector voltage of the transistor T3 is input to the control circuit 15 as the reception signal S5 via the resistor R21.

The structure of the transmission / reception unit P2 will be described. First, the transmitting side T will be described. The signal output from the output terminal OUT of the transmission buffer P1 is input to the base of the PNP transistor T4 via the resistor R22. The base of the transistor T4 has a resistance R to the power supply voltage (5 [V])
It is connected via 23. A capacitor C5 and an electric field capacitor C connected in parallel between the power supply voltage and the ground
12 and 12 are connected. The emitter of the transistor T4 is connected to the power supply voltage. The collector of the transistor T4 is grounded via an infrared light emitting diode LED connected in series and a resistor R24. As a result, the transistor T4 is turned on / off according to the signal from the output terminal OUT, and the infrared light emitting diode LED blinks accordingly.

The receiving side R will be described. The infrared light receiving circuit PD has a phototransistor (not shown), operates at a power supply voltage of 5 [V], converts the received infrared light into an electric signal, and outputs the electric signal. A capacitor C6 and an electric field capacitor C13, which are connected in parallel, are connected between the power supply terminals of the infrared light receiving circuit PD. The electric signal output from the infrared light receiving circuit PD is output to the input terminal IN of the transmission / reception buffer P1 via the resistor R25.

In the main body 300, the transmission / reception buffer P1
And the transmission / reception unit P2, and the power cutoff circuit 1
3, the current detection circuit 14, the control circuit 15 and the primary side coupling circuit 12 are electrically connected to each other via a harness connection connector K1. In the door 400, the harness connection connector K is provided between the liquid crystal unit 25 and each of the secondary side coupling circuit 21, the transmission / reception unit P2.
It is electrically connected via 2. The liquid crystal unit 25 includes a liquid crystal panel 22, a transmission / reception buffer of the infrared communication circuit 23, and a control circuit 24.

Next, infrared communication between the main body 300 and the door 400 will be described. In the main body 300, the transmission signal S4 output from the control circuit 15 is transmitted / received by the transmission / reception buffer P.
1 is transmitted from the transmission / reception unit P2 as infrared rays. The signal transmitted from the main body 300 is received by the transmission / reception unit P2 of the door 400 and input to the control circuit 24 via a transmission / reception buffer (not shown) in the liquid crystal unit 25. On the door 400 side, the contents displayed on the liquid crystal panel 22 according to the signal received by the control circuit 24, the presence / absence of the display on the liquid crystal panel 22, the presence / absence of the lighting of the backlight at the time of performing the display on the liquid crystal panel 22, etc. Control.

The transmission signal output from the control circuit 24 on the door 400 side is transmitted as infrared rays from the transmission / reception unit P2 via a transmission buffer (not shown). The signal transmitted from the door 400 is received by the transmission / reception unit P2 of the main body 300, becomes a reception signal S5 via the transmission / reception buffer P1, and is input to the control circuit 15. Body 3
On the 00 side, the operating state of the liquid crystal display panel 22 of the door 400 is recognized based on the reception signal S5 received by the control circuit 15.

The operation of the control circuit 15 on the main body 300 side will be described with reference to the flowchart shown in FIG. Body 3
When the power of 00 is turned on, the power supply to the primary side coupling circuit 12 is started (step # 210). Next, the operation of the primary side coupling circuit 12 is started (step # 220).
Next, the liquid crystal panel 22 of the door 400 is set to a state in which no liquid crystal display is performed, that is, a state where the load on the secondary side coupling circuit 21 is small (hereinafter, referred to as "power saving mode") (step # 230).

According to the ambient temperature T of the primary side coupling circuit 12 detected by the temperature sensor 17, a current limit value I _LIMIT (I1, I described later) stored in the memory 15A in advance.
M and IL are applicable and stored (step #
235). That is, when the ambient temperature T is 0 ° C. or lower,
Stores plus the temperature correction value [Delta] I _t1 to the current limit value I _LIMIT as a new current limit value I _LIMIT. If the ambient temperature T is 45 ° C. or higher, the current limit value I _LIMIT plus the temperature correction value ΔI _t2 is newly added to the current limit value I
Remember as _LIMIT . When the ambient temperature T is higher than 0 ° C. and lower than 45 ° C., the current limit value I _LIMIT previously stored in the memory 15A is stored as it is. still,
In the present embodiment, the temperature correction is performed when the ambient temperature T is 0 ° C. or lower and 45 ° C. or higher, but the present invention is not limited to this numerical value, and the temperature correction is performed according to the ambient temperature T. I wish I had it.

Next, it is judged whether or not the current value I _R of the primary side coupling circuit 12 is less than or equal to the current limit value I1 when the load of the secondary side coupling circuit 21 is small (step # 24).
0). The current value I _R of the primary side coupling circuit 12 is the current limit value I
If it is 1 or less (Y in step # 240), the process proceeds to step # 260 described later. On the other hand, the primary side coupling circuit 12
If the current value I _R is not less than or equal to the current limit value I1 (N in step # 240), it is determined to be an overcurrent, and the power supply cutoff circuit 13 cuts off the power supply to the primary side coupling circuit 12 by the power supply control signal S1. ON / OFF control signal S2
Thus, the operation of the primary side coupling circuit 12 is stopped (step # 250). It should be noted that, when power supply to the primary side coupling circuit 12 is cut off, it is desirable to be configured to give a warning to that effect.

In step # 260, the primary side coupling circuit 1
2 current value I_RAnd the load on the secondary side coupling circuit 21 is small
Reference current value i₀Difference value Δi₀(Δi₀= IR-
i₀) Is calculated and the back is displayed on the liquid crystal panel 22 of the door 400.
LCD display without turning on the light (hereinafter, "Medium
Current limit value IM and difference value Δi in “load mode”)
₀The sum of and the medium load mode threshold IM_thWhen you memorize as
When the backlight is turned on and the liquid crystal display is displayed
Current limit value IL (hereinafter referred to as "heavy load mode")
And the difference value Δi₀The sum of and the heavy load mode threshold IL_thAs
Remember. Cancel saving mode after step # 260
Then switch to medium load mode or heavy load mode
(Step # 270), move to the next step # 280
It

In step # 280, it is determined whether or not communication with the control circuit 24 on the door 400 side is good. If the communication is good (Y in step # 280), the process proceeds to step # 290 described later. On the other hand, if the communication is not good (N in step # 280), it is determined that the power supply is abnormal or the communication is interrupted due to the inclusion of foreign matter, and the process proceeds to step # 250 described above. The power supply to the primary side coupling circuit 12 is cut off and the operation of the primary side coupling circuit 12 is stopped.

At step # 290, the primary side coupling circuit 1
It is determined whether or not the current value I _{R of} 2 is equal to or less than the medium load mode threshold IM _th in the medium load mode, and is equal to or less than the large load mode threshold IL _{th in the} heavy load mode. If the current value I _R of the primary side coupling circuit 12 is equal to or smaller than the threshold value corresponding to each mode (Y in step # 290), the process proceeds to # 280 described above. On the other hand, if the current value I _R of the primary side coupling circuit 12 is not less than or equal to the threshold value corresponding to each mode (N in step # 290), it is determined to be overcurrent,
By shifting to step # 250, the power supply to the primary side coupling circuit 12 is cut off and the operation of the primary side coupling circuit 12 is stopped.

With the above configuration, even when the load of the secondary side coupling circuit can be in a plurality of states or when the ambient temperature of the primary side coupling circuit changes, the threshold value for overcurrent detection is set for each load. Since the current limit value stored in advance is corrected based on the temperature-corrected value, it is possible to absorb the component variation and the environment variation and perform the overcurrent detection with high accuracy. This makes it possible to detect even a minute increase in current due to foreign matter such as metal mixed in between the primary side coupling circuit and the secondary side coupling circuit. As a result, when foreign matter is mixed in, the power supply to the primary side coupling circuit is cut off, whereby heat generation of foreign matter can be prevented and safety is improved.

In the second embodiment, in the flow chart shown in FIG. 7, the process proceeds to step # 250 to cut off the power supply to the primary side coupling circuit 12 and stop the operation of the primary side coupling circuit 12. After a predetermined time has elapsed, the process proceeds to step # 210 so that power is supplied to the primary side coupling circuit 12 and the primary side coupling circuit 1 is connected.
The operation of 2 may be automatically restored.

Next, a refrigerator according to a third embodiment of the present invention will be described. The block diagram is the same as that of the refrigerator of 2nd Embodiment shown in FIG. The operation of the control circuit 15 on the main body 300 side in the refrigerator of the third embodiment will be described using the flowchart shown in FIG. The same parts as those of the operation of the control circuit 15 in the refrigerator of the second embodiment shown in the flowchart of FIG. 7 are designated by the same reference numerals, and the description thereof will be omitted.

If the result of determination in step # 290 is that the current value of the primary side coupling circuit 12 in the normal mode is normal (Y in step # 290), it is determined whether or not the door 400 is open (step ##). 300). If the door 400 is not open (N in step # 300), step # 28
Move to 0. On the other hand, if the door 400 is open (Y in step # 300), the operation of the primary side coupling circuit 12 is stopped by the ON / OFF control signal S2 (step # 3).
10). After step # 310, if the door 400 is closed (Y in step # 320), step # 22
Move to 0.

With the above configuration, each time the door 400 is changed from the open state to the closed state, the difference between the actual current value of the primary side coupling circuit 12 and the reference current value is calculated. However, by adding the difference value to the current limit value, the operation of correcting the threshold value for overcurrent detection is performed, so it becomes possible to absorb changes in the environmental conditions in which the equipment is installed. As a result, more accurate overcurrent detection can be performed, and safety can be further improved.

In the refrigerators of the second and third embodiments, when the temperature rises above the threshold value, the temperature fuse (not shown) is cut off and the primary side coupling circuit 12 is mechanically fed with power. Although it may be possible to generate heat due to factors other than overcurrent or foreign matter mixing, it is still possible to prevent damage to the equipment or the user due to heat generation. And the safety is improved.

Also in the mobile phone of the first embodiment, the temperature sensor 17 is provided around the primary side coupling circuit 12 as in the refrigerators of the second and third embodiments. The current limit value stored in advance in the memory 15A may be corrected according to the temperature.

[0052]

As described above, according to the present invention,
The threshold for overcurrent detection is corrected according to the actual current value, and the threshold for overcurrent detection is updated every time the load status is changed. Overcurrent detection can be performed. This makes it possible to detect even a minute increase in current due to foreign matter such as metal mixed in between the primary side coupling circuit and the secondary side coupling circuit. Therefore, when the foreign matter is mixed, the heat generation of the foreign matter can be prevented by cutting off the power supply to the primary side coupling circuit, and the safety is improved.

Further, according to the present invention, even when the load of the secondary side coupling circuit is divided into multiple stages or when the ambient temperature of the primary side coupling circuit changes, overcurrent detection is performed for each load. Since the threshold value is corrected based on the current limit value stored in advance and the temperature is corrected, the above effect can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram of a set of a mobile phone according to a first embodiment of the present invention and a charger thereof.

FIG. 2 is a circuit diagram showing a detailed configuration of a set with a charger of the mobile phone according to the first exemplary embodiment of the present invention.

FIG. 3 is a flowchart showing an operation performed by a control circuit provided in the mobile phone according to the first embodiment of the present invention.

FIG. 4 is a block diagram of a refrigerator that is a second embodiment of the present invention.

FIG. 5 is a circuit diagram showing a detailed configuration of a refrigerator that is a second embodiment of the present invention.

FIG. 6 is a circuit diagram showing a detailed configuration of a refrigerator that is a second embodiment of the present invention.

FIG. 7 is a flowchart showing an operation performed by a control circuit provided in the refrigerator which is the second embodiment of the present invention.

FIG. 8 is a flowchart showing an operation performed by a control circuit provided in the refrigerator which is the third embodiment of the present invention.

[Explanation of symbols]

11 power supply 12 Primary side coupling circuit 13 Power cutoff circuit 14 Current detection circuit 15 Control circuit 15A memory 16 infrared communication circuit 17 Temperature sensor 20 load 21 Secondary side coupling circuit 22 LCD panel 23 Infrared communication circuit 24 Control circuit 25 LCD unit 100 charger 121 coils 122 Primary side non-contact power supply unit 200 mobile phones 211 coils 212 Secondary side non-contact power supply unit 300 refrigerator body 400 doors CTL control terminal GND ground terminal OUT output terminal IN input terminal S1 power supply control signal S2 ON / OFF control signal S3 current detection signal S4 transmission signal S5 received signal T1 to T4 transistors R1 to R25 resistance C1 to C6 capacitors C11 to C13 electric field capacitors OP1, 2 operational amplifier LED infrared light emitting diode P1 send / receive buffer P2 transceiver unit T Transmission / reception unit P2 transmission side R Receiver / receiver unit P2 receiver PD infrared light receiving circuit K1, K2 harness connection connector

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-11-283854 (JP, A) JP-A-11-178232 (JP, A) JP-A-11-122832 (JP, A) JP-A-6- 311658 (JP, A) JP 9-103037 (JP, A) Jpn 7-871 (JP, Y2) Jpn 7-47957 (JP, Y2) (58) Fields investigated (Int.Cl. ⁷ , DB name) H02J 7 / 00,17 / 00 H01F 38/14 F25D 11 / 00,23 / 00,29 / 00

Claims (3)

(57) [Claims] 1. A main body and a separate body which is detachable from the main body. When the separate body is attached to the main body, a primary side coupling circuit provided in the main body and a secondary side provided in a separate body. With an electrical device that is electromagnetically coupled with a coupling circuit, and the load of the secondary side coupling circuit can assume a plurality of states, current detection means for detecting a current value of the primary side coupling circuit, and the primary side coupling circuit A storage unit that stores in advance a reference current value and a current limit value of the primary side coupling circuit; and a correction value calculation unit that calculates a difference value between the current value actually measured by the current detection unit and the reference current value. An overcurrent detection unit that detects an overcurrent of the primary side coupling circuit by using a value obtained by adding the current limit value and the difference value as a threshold value; and, if an overcurrent is detected, the primary side coupling circuit. Power supply system that cuts off power supply to And means, which has a electrical apparatus, characterized by updating the difference value after calculation at the correction value calculating means each time the load state of the further body is changed. 2. A main body and a separate body that is detachable from the main body. When the separate body is attached to the main body, the primary side coupling circuit provided on the main body and the secondary side provided on a separate body. In an electric device that is electromagnetically coupled with a coupling circuit, and the load of the secondary side coupling circuit can take a plurality of states, current detection means for detecting a current value of the primary side coupling circuit, and depending on the state of the load. A storage unit that stores in advance a current limit value of the primary side coupling circuit and a reference current value of the primary side coupling circuit in a state where the load is minimum, and detects a temperature around the primary side coupling circuit. And a first overcurrent detecting unit for detecting an overcurrent of the primary side coupling circuit by setting a load of the secondary side coupling circuit to a minimum and setting a current limit value in a state where the load is the minimum as a threshold value. The current detecting means and the first overcurrent detecting means When the overcurrent is not detected, a correction value calculating means for calculating a difference value between the current value actually measured by the current detecting means and the reference current value, and a state in which the load of the secondary side coupling circuit is not minimum. Then, the second overcurrent detection for detecting the overcurrent of the primary side coupling circuit with a value obtained by adding the current limit value of the primary side coupling circuit and the difference value according to the state of the load as a threshold value. Means and power supply control means for shutting off power supply to the primary side coupling circuit when an overcurrent is detected by the first or second overcurrent detection means, and the temperature detection means detects the overcurrent. Depending on the temperature
Correction of the current limit value stored in advance by the storage means
After that, by the first or second overcurrent detection means
An electric device characterized by detecting overcurrent . 3. A which has a temperature detecting means for detecting the temperature around the primary coupling circuit, in accordance with the detected temperature by said temperature detecting means, before
Correction of the current limit value stored in advance by the storage means
After that, the overcurrent is detected by the overcurrent detecting means, and the electric device according to claim 1.