KR950009664Y1 - Output control device of electronic cooker - Google Patents

Abstract

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Description

Output control device of electronic cooker

1 is a block circuit diagram showing the configuration of an electronic cooker of an embodiment to which the present invention is applied.

2 is a graph showing a change in heat pipe temperature.

FIG. 3 is a circuit diagram showing a specific circuit configuration example of main parts of the electronic cooker shown in FIG.

* Explanation of symbols for main parts of the drawings

15: temperature detection element 17: power increase circuit

18: gate circuit 24: thermistor

31,35: Transistor

The present invention relates to an output control device for an electronic cooker for controlling the output of the electronic cooker.

The present invention is an output control device of an electronic cooker, which increases the input power temporarily and returns the input power to a normal value before the temperature of the component reaches the maximum allowable temperature, thereby using at normal temperature. In this regard, it is possible to fully demonstrate the capability of the parts and to improve the ease of use of the electronic cooker.

BACKGROUND ART Conventionally, an electronic cooker which supplies electric power to a work coil and heats it by electromagnetic induction, such as a pot placed on the work coil, is generally known (see Japanese Patent Application No. 53 (1978) -55866, etc.). ). This electronic cooker has a relatively high rated power in general household electrical appliances, and there is considerable heat generation of components. Therefore, even if it is used in the upper limit (for example, room temperature of about 40 degreeC) of surrounding ambient temperature, it is designed so that the temperature of a component may not exceed the maximum allowable temperature.

As described above, the design of the electronic cooker is usually performed in accordance with the maximum allowable temperature of the component. Therefore, when it is used at normal temperature (for example, about 20 ° C), the operation with a considerable margin of temperature is performed. That is, in use at normal temperature, the capability of the component was not fully utilized.

Therefore, the present invention has been proposed in view of the above-mentioned conventional problems, and it is to provide an output control apparatus for an electronic cooker that can fully exhibit the capability of parts and improve the convenience of use in use at normal temperature. The purpose.

The output control device of the electronic cooker according to the present invention is the output control device of the electronic cooker for controlling the output of the electronic cooker by controlling the input power, in order to achieve the above object, the input power of the normal value in normal use Power supply means for supplying a power supply, temperature detecting means for detecting a temperature of a component whose temperature changes according to the magnitude of the input power, power increasing means for increasing the input power above the normal value, and inputting the normal value or more. And power control means for controlling the input power to return to the normal value before the temperature of the component which rises with increasing power reaches the maximum allowable range in accordance with the detection output from the temperature detecting means.

According to the present invention, the input power is temporarily increased, thereby returning the input power to the normal value before the temperature of the rising component reaches the maximum allowable temperature.

Next, an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a block circuit diagram showing the configuration of an electronic cooker of the embodiment to which the present invention is applied. The AC power supply 1 is connected to the input terminal of the diode bridge 2, and the capacitor | condenser 3 for rectifying output is connected between the output terminals of this diode bridge 2. As shown in FIG. One end of the condenser 3 is connected to the choke coil 4 for high frequency suppression, and the coil 4 is connected to the work coil (output coil) 5 and the condenser 6 for resonance. Connected to the parallel circuit and the capacitor 7 for the filter. The parallel circuit formed by the work coil 5 and the condenser 6 is connected to the damper diode 8 and the output transistor 9, respectively.

The AC power supply 1 is connected to a power supply circuit 10, and the output from the power supply circuit 10 is supplied to the oscillation control circuit 11. The oscillation control circuit 11 outputs a signal (voltage) according to the setting of the variable resistor 12 and outputs a square wave signal having a repetition frequency according to the signal from the oscillation circuit 13. The square wave signal from the oscillation circuit 13 is supplied to the base of the output transistor 9 through the driving circuit 14, so that the transistor 9 is turned on and off. As the output transistor 9 is turned on and off, a pot or the like placed on the work coil 5 is inductively heated.

In addition, a heat detector (not shown) of the output transistor 9 is provided with a temperature detecting element 15 such as a thermistor as a temperature extracting means. The output of the temperature detecting element 15 is sent to the temperature detecting circuit 16 so that the temperature of the heat sink of the output transistor 9 is detected, that is, the temperature of the output transistor 9 is indirectly detected. The output from the power increasing circuit 17, which is a power increasing means, is the power control means and is controlled by the oscillation control circuit through the gate circuit 18 and the manual switch 19, which are opened and closed by the output from the temperature detection circuit 16. Is sent to (11). As a result, the upper limit of the voltage variable range by the variable resistor 12 rises, the oscillation frequency of the oscillation circuit 13 decreases, and the input power increases. Here, the temperature of the output transistor 9 changes according to the magnitude of the input power. Further, before the temperature of the heat sink of the output transistor 9 rising by the power increasing circuit 17 reaches the maximum allowable temperature, the gate circuit 18 is opened by the output from the temperature detection circuit 16, The input power is returned to the normal value.

Next, the use at the normal temperature (for example, about 20 degreeC) of the above-mentioned electronic cooker is demonstrated. Normally, the switch 19 is turned off, and the upper limit of the voltage variable range by the variable resistor 12 is a normal value. The oscillation circuit 13 outputs a quadrature wave signal having a repetition frequency according to the setting of the variable resistor 12, and the output transistor 9 is turned on and off by this quadrangle wave signal. As the output transistor 9 is turned on and off, a current flows through the work coil 5, and a pot or the like placed on the work coil 5 is inductively heated. In this normal use state, for example, the input power is P ₀ , and the temperature of the heat sink of the output transistor 9 rises with the passage of time, as indicated by A in FIG. 2, and finally the temperature T _It reaches _N and converges.

On the other hand, when the switch 19 is turned on from t ₀ at the start of use, the output from the power increase circuit 17 is sent to the oscillation control circuit 11 through the gate circuit 18 and the switch l9. The upper limit of the voltage variable range by the variable resistor 12 rises. As a result, the oscillation frequency, that is, the repetition frequency of the square wave signal output from the oscillation circuit 13 is lowered, and the input power is increased. The input power at this time is, for example, P ₁ (> P ₀ ), and the temperature change of the heat sink of the output transistor 9 is a curve whose change is more sharp than the curve A described above, as indicated by B in FIG. do. The gate circuit 18 is opened at t ₁ just before the temperature reaches the maximum allowable temperature T _MAX by the output from the temperature detection circuit 16, and the repetition frequency of the square wave signal from the oscillation circuit 13 is increased. It is returned to the original, and the input power is returned to the normal value P ₀ . Therefore, after this time t ₁ , the temperature is lowered and converged to the convergence temperature T _N in the normal use state.

In this way, when the switch 19 is turned on, the period until the temperature of the heat sink of the output transistor 9 reaches the maximum allowable temperature T _MAX , and the period of t ₀ to t ₁ in FIG. Since the increasing state P ₁ is continued, it boils faster than usual input power P ₀ , for example, when water is to be boiled quickly, and is very convenient for use. In addition, when the ambient temperature rises for some reason, the increase period of the input power is shortened, the temperature of the heat sink does not exceed the maximum allowable temperature T _MAX , and the reliability of the output transistor 9 is not deteriorated.

The temperature detecting element 15 may be attached directly to the output transistor 9.

Next, a specific circuit configuration example of the main portion is shown in FIG. The voltage controlled oscillation circuit (VCO) 21 corresponding to the oscillation circuit 13 is connected to the driving circuit 22 corresponding to the driving circuit 14, and the driving circuit 22 is the work coil ( 5) or an output circuit 23 corresponding to an output circuit section formed of the output transistor 9 or the like. In addition, the thermistor 24 corresponding to the temperature detecting element 15 is grounded at one end thereof, and the other end thereof is an oscillation input of the voltage comparator 25 corresponding to the temperature detecting circuit 16. It is connected to the power supply terminal 27 via a terminal and a resistor 26. The non-inverting input terminal of the voltage comparator 25 is grounded through the resistor 28 and connected to the power supply terminal 27 through the resistor 29. The output terminal of the voltage comparator 25 is connected to the base of the transistor 31 corresponding to the gate circuit 18 via a resistor 30. The collector of this transistor 31 is connected to the light emitting diode 33 for display via the diode 32, and the base of the transistor 35 corresponding to the power increasing circuit 17 via the diode 34. Is connected to. The collector of the transistor 35 and the light emitting diode 33 are connected to the power supply terminal 27 via a switch 36 corresponding to the switch 19. The emitter of the transistor 35 is connected to the connection point of the resistor 37 and the variable resistor 38 in a series circuit composed of the resistor 37, the mask resistor 38, and the resistor 39. The resistor 37 is connected to the power supply terminal 40 and the variable resistor 38 is connected to the voltage controlled oscillation circuit 21. The variable resistor 38 is integrated with the switch 36, for example, and has a click at a position where the variable resistor 38 is further turned beyond the maximum level of the adjustment range, and at this click position, the switch 36 ) Is turned on.

In the electronic cooker configured as described above, when the switch 36 is turned on, the bladder diode 33 is turned on to indicate that the input power increase operation is in progress. Now, considering the use at normal temperature, the output of the voltage comparator 25 is at a low level, and the transistor 31 is off and the transistor 35 is on. Therefore, the upper limit of the voltage variable range of the variable resistor 38 is increased by this transistor 35, the voltage supplied to the voltage controlled oscillation circuit 21 is increased, the oscillation frequency is lowered, and the input power is increased. Then, the temperature of the heat sink of the output transistor in the output circuit 23 rises so that the resistance of the thermistor 24 decreases. It turns on and turns off the transistor 35. Thus, the light emitting diode 33 is turned off, the upper limit of the voltage variable range of the variable resistor 38 is returned to its original state, the oscillation frequency of the voltage controlled oscillation circuit 21 is returned to its original state, and the input power is returned to its normal value. Lose.

When the switch 36 is turned off, the variable resistor 38 operates in a normal variable range.

In place of the output transistor, the temperature of the work coil or the damper diode may be detected. It is also possible to detect the change in temperature by the change of V _BE (voltage between base and emitter) of the output transistor.

In the output control apparatus of the electronic cooker of the present invention, the input power is temporarily increased to return the input power to the normal value before the temperature of the component reaches the maximum allowable temperature. Therefore, in use at normal temperature, the capability of the component can be sufficiently exhibited, and there is no adverse effect on the reliability of the component. In addition, when high power is required, for example, when water is to be boiled quickly, it is boiled faster than usual and the convenience of using an electronic cooker can be improved.

Claims (1)

An output control apparatus of an electronic cooker which controls the output of the electronic cooker by controlling the input power, comprising: power supply means for supplying the normal input power in normal use, and a temperature varying in accordance with the magnitude of the input power; Temperature detecting means for detecting the temperature of the component, power increasing means for increasing the input power above the normal value, and temperature of the component rising in accordance with the increase of the input power above the above-mentioned value to reach the maximum allowable range. And a power control means for performing control to return the input power to the normal value according to the detection output from the temperature detecting means.