JPH0372285B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a rice cooker control device.

In general, automatic rice cookers controlled by a microcomputer have a regular heating pattern, that is, a mode in which preheating → high heating → medium heating → maintaining boiling → uneven heating → keeping warm is performed by program control.
It has a mode in which heating is performed with a constant power without relying on this program control, and heating is stopped when the moisture content disappears and the temperature rises to a predetermined value.

Conventionally, in this non-program controlled mode, if the temperature detection device fails, the rice cooker is heated to a high temperature that activates the temperature fuse, or if the temperature detection device fails, the power to the rice cooker is automatically turned off. . In the former case, the operating point of the temperature fuse is high enough to cause thermal damage to the rice cooker, and in the latter case, the rice cannot be cooked and must be re-cooked using another method. It is necessary to do this.

The present invention has been made in view of the above problems, and its purpose is to turn off the power after a predetermined period of time when rice cooking is started in a mode that is not based on program control, thereby preventing thermal damage to the rice cooker. To provide a control device for a rice cooker that prevents the addition of rice and avoids re-cooking.

An embodiment of the present invention will be described below.

FIG. 1 schematically shows the configuration of the present invention.

1 is a rice cooking heater provided to heat the bottom surface of the inner pot 2 of the rice cooker A via a heat transfer member 3; 4 is a heat-retaining heater; It is provided to heat the upper side. 6 is a temperature detection means including a thermistor 6-1 as an example of a temperature measuring element;
is provided so as to be in contact with the bottom surface of the inner pot 2. Reference numeral 7 denotes a rice cooking mode setting means which stores a rice cooking mode program using temperature and time as parameters, and is usually constituted by a ROM. 8 is a rice cooking mode control means which inputs the temperature signal from the temperature detection means 6 and the time signal from the time measurement means 9, and controls the rice cooking heater 1 and heat retention according to the rice cooking mode program set in the rice cooking mode setting means 7. It outputs a signal that controls the on/off operation of the heater 4 and the amount of electricity supplied to the rice cooking heater 1. Reference numeral 10 denotes heater energization amount control means, which inputs a signal from the rice cooking mode control means 8 and determines the amount of energization to the rice cooking heater 1 . Reference numeral 11 denotes a switch means which inputs a signal from the rice cooking mode control means 8 and controls the ON/OFF operation of energizing the rice cooking heater 1 and the warming heater 4.

In the present invention, if a temperature signal higher than a certain temperature is sent from the temperature detection means 6 to the rice cooking mode control means 8 before reaching a predetermined rice cooking mode or within a certain period of time, the rice cooking mode control means 8 sends a signal to the switch means 11. is sent out, the power supply to the rice cooking heater 1 is turned off, and the power supply to the warming heater 4 is controlled to be turned on.

In addition, in a preferred embodiment of the present invention,
As shown in FIG. 1, there is also a thermistor 12-1 for detecting the side temperature of the inner pot 2;
Temperature detection means 12 including 2-1 and rice cooking power determination means 13 are provided.

The rice cooking power determining means 13 measures the rate of temperature increase over a certain period of time from the temperature detecting means 12 to determine the amount of content in the inner pot 2, and controls the heater energization amount control means 10 to determine the amount of heater energization according to the capacity. send a signal to. Further, the heater energization amount control means 10 inputs a signal from the temperature detection means 12 at the time of starting rice cooking, and if the starting temperature is high, the heater energization amount is reduced.
On the other hand, if the starting temperature is low, control is performed to increase the amount of current supplied to the heater. Furthermore, in the initial state (when the power is turned on), the rice cooking mode control means 8 inputs a signal from the temperature detection means 12, and the inner pot temperature is determined by inputting the signal from the temperature detection means 12.
If the temperature is 55° C. or higher, control may be performed to turn off electricity to the rice cooking heater 1 and shift to the heat retention mode.

FIG. 2 shows a schematic sectional view of one embodiment.

Reference numeral 20 denotes a control unit installed on the outer body of the rice cooker, and a microcomputer 21 as a control circuit for realizing each means shown in FIG. 1 is built inside the control unit. 22 to 24 are various switches for operating this microcomputer 21. The thermistors 6-1 and 12-1 are brought into contact with the bottom and side surfaces of the inner pot 2, respectively, by the pressing force of the spring, and the detection signals of both thermistors 6-1 and 12-1 are input to the microcomputer 21. is connected to. 25 is a power supply circuit which receives a control signal from the microcomputer 21 and energizes the rice cooking heater 1 and the warming heater 4. Rice cooking heater 1
is embedded in the heat transfer member 3 that contacts the bottom surface of the inner pot so that the heat generated therefrom is effectively transferred to the bottom surface of the inner pot. The heat-retaining heater 4 is connected to the inner pot 2 via the outer container 5.
It is provided surrounding the upper side surface of the outer container 5 so that heat is transferred thereto. 26 is the lid of the inner pot.
Although not shown in the figure, a heat insulating material is filled around the outer container 5 for heat retention, and a lid 26 is also provided.
A known pressure regulating device can also be provided. 19
is a micro switch that detects the presence or absence of inner pot 2,
If the inner pot 2 is present, it is turned on and the power supply circuit 25 is turned on, and until the inner pot 2 is placed, the power supply circuit 25 is turned off to prevent empty cooking.

In this embodiment, an electric circuit system directly related to the operation of the rice cooking heater 1 is shown in FIG. Thermistor 6-1 on the bottom side of the inner pot and thermistor 12- on the side side
1 is a power supply via resistors R1 and R2, respectively.
It is provided between V _DD and ground, and each detection signal is input to A/D converter input ports K2 and K1 of the microcomputer 21 and converted into a digital signal. Switch 22 is a rice cooking switch for operating the rice cooking operation, and switch 23 is a switch for setting the timer since this embodiment has a timer function as described later.
Signals from the respective switches 22 and 23 are also input to the microcomputer 21.

The microcomputer 21 controls the gate signal of the triac 28 via the driver 27 by sending an on/off signal to the driver 27. The rice cooking heater 1 is connected to an AC power source 29 via its triax 28, and is controlled to be turned on and off.

In this embodiment, the amount of electricity supplied to the rice cooking heater 1 is controlled by the duty ratio of the on-time controlled via the triax 28. That is, the microcomputer 21 controls the thermistors 6-1 and 12-.
When the temperature signal from 1 is input, the driver 27 outputs an ON signal for an appropriate amount of time at regular intervals (for example, 15 seconds) so that the amount of power to the heater is appropriate according to the set rice cooking mode program.
The triax 28 is turned on. Since the rice cooking heater 1 is energized and heated only during the time when the triator 28 is on, the desired amount of energization (cooking power) can be adjusted by changing the energized time.
It becomes.

FIG. 4 shows a panel of the control unit 20 in this embodiment.

The switches that the operator can operate include rice cooking switch 2, which is used to start and stop the rice cooking operation.
2. There are three switches: a timer switch 23 that allows you to set the time until the start of the rice cooking operation, and a browning switch 24 that allows you to adjust the degree of burning according to your preference. 30
is a display panel that displays the progress of rice cooking as it progresses according to the program.
8 are provided, and are sequentially lit one by one as the program progresses. 40 and 41 are time display panels that display the remaining time until the rice cooking operation starts when the timer is set by the timer switch 23, 40 is a single digit 7 segment LED element indicating the time, and 41 is a number 30. The displayed surface light emitting element represents the minutes.

Next, the operation of one embodiment will be explained.

FIG. 5 shows the relationship between the rice cooking mode program executed in one embodiment and the bottom temperature of the inner pot.

At the beginning of the rice cooking operation, the rice is cooked at a low temperature for sufficient moisture absorption, for example, for 6 minutes. This stage is called preheating mode. Next, increase the power of the rice cooker to the maximum. This stage is called middle Patsupa mode. Then, when the temperature on the side of the inner pot exceeds 50°C, the amount of content is determined, and the power supply is controlled according to the amount. This stage is called power control mode. In this mode it will eventually boil over. After starting the power control mode, the rice cooking heater power is reduced to 30% for a certain period of time.
% to maintain a boiling state. This stage is called boiling maintenance mode. As the water continues to boil, the water will eventually disappear and the temperature will begin to rise. When the temperature reaches 137℃, it will enter uneven mode.
In the uneven mode, after the rice cooking heater 1 is turned off for a certain period of time, the rice cooking heater 1 is turned on for a time corresponding to the set value of the burn switch 24, and then turned off again to complete the rice cooking operation and enter the warming mode. In the heat retention mode, the rice temperature is controlled to be 70° C. by turning on and off the heat retention heater 4.

The above is a normal rice cooking operation, but for example, in the power control mode, the temperature at the bottom of the inner pot has already reached
When the temperature reaches 137°C or higher, it is determined that the inner pot is empty, and the subsequent program steps are skipped and the system shifts to the keep warm mode. In addition, if the thermistor installed on the side of the inner pot is not normal, rice cannot be cooked according to the program, so the normal rice cooking mode with constant power of the rice heater will be executed, but in that case, after starting the normal rice cooking mode, , If the temperature at the bottom of the inner pot reaches 137℃ or higher within a certain period of time,
After all, it determines that the inner pot is empty and shifts to keep warm mode.

The above operation will be explained in more detail according to the flowchart.

FIG. 6 represents the initial state. When the power is turned on, first, an abnormality in the thermistor 6-1 (hereinafter referred to as the first thermistor) on the bottom of the inner pot is detected (step S1). Abnormality detection is performed as follows. If the thermistor is disconnected, it will have high resistance and will be in the same state as at low temperatures, and if it is shorted, it will be low in resistance and will be in the same state as at high temperatures. Here, in the initial state, the resistance value of the first thermistor 6-1 is -
If the resistance value is high corresponding to a temperature below 20°C or low resistance value corresponding to a temperature above 150°C, it is determined that the first thermistor 6-1 is abnormal, and the abnormality is notified. Next, the temperature is detected by the thermistor 12-1 (hereinafter referred to as the second thermistor) on the side surface of the inner pot (step S2). If the side surface of the inner pot is 55°C or higher, the mode shifts to keep warm mode, and if the temperature is lower than 55°C, the timer switch 23 and rice cooking switch 22 are read. If the timer switch 23 is on, the mode shifts to the timer set mode (step S3), and if the timer set switch 23 is off and the rice cooking switch 22 is on, the mode shifts to the preheating mode (step S4).

FIG. 7 shows an operational flowchart of the heat retention mode. The insulating heater 4 is controlled so that the rice temperature reaches 70°C (step S5). If the rice cooking switch 22 is pressed during the keep warm mode, the rice cooker will stop (step
S6). Also, the second thermistor 1 is
2-1 abnormality is detected (step S7). The abnormality detection of the second thermistor 12-1 is also performed by the first thermistor 6.
It is the same as the case of -1, but in this case, if the resistance value is high corresponding to 20°C or lower, or low resistance value is 130°C or higher, it is determined to be abnormal.

A flowchart of the timer set operation is shown in FIG. When the timer switch 23 is pressed, the set time is displayed (step S11), and each time the timer switch 23 is pressed, the time display is incremented by 30 minutes (step S11).
S12, S13). Then, when the rice cooking switch 22 is pressed (step S10), the timer operation is started.

A flowchart of the timer operation is shown in FIG. The elapsed time is subtracted from the displayed set time, the remaining time is displayed (step S15), and when the remaining time reaches 0, the mode shifts to preheating mode (step S16). If the rice cooking switch 22 is pressed during this timer mode (step S14), the timer set is canceled and the process returns to the initial state.

Next, the rice cooking operation will be explained with reference to FIGS. 10 to 14.

In the preheating mode (Fig. 10), first, the inner pot temperature is measured by the second thermistor 12-1, and the appropriate power is applied depending on whether it is below 20℃, 20 to 33℃, or 33℃ or above. Rice cooking heater 1
Electrify and heat (steps S20, S21). After preheating for a certain period of time (for example, 6 minutes), the electric power of the rice cooking heater 1 is increased to the maximum, and the rice cooker shifts to the next medium heat mode (steps S23 and S24).

If the rice cooking switch 22 is pressed in this preheating mode, if the timer switch 23 is not on when the rice cooking switch 22 is released and turned off, the rice cooking operation is canceled and returns to the initial state (step S22 → S40, S41). This operation is performed when you have started cooking rice but want to stop it for some reason. Also, if the timer switch 23 is pressed when the pressed rice cooking switch 22 is released,
Shift to normal rice cooking mode (steps S22→S40,
S41). This operation is performed in an inspection process before shipment at a factory.

In the medium-temperature mode (Fig. 11), if the temperature detected by the second thermistor 12-1 is less than 37°C, the medium-temperature operation will continue, but if the second thermistor 12-1 detects a temperature of 37°C or higher at this point. If so, the second
Since there is a possibility that the thermistor 12-1 is abnormal or the rice is being cooked dry, the rice cooking mode is shifted to the normal rice cooking mode (step S25).

Under normal conditions, the second thermistor 12-1 becomes 50% within a certain period of time (for example, 10 minutes) after the start of the medium-pump operation.
Detect the temperature (steps S26, S27). However, even after a certain period of time has passed, the second thermistor 12-1 remains at 50°C.
If not detected, it is determined that there is an abnormality in the second thermistor 12-1 or the like, and the mode is shifted to the normal rice cooking mode (step S26).

At step S27, the second thermistor 12-1 becomes 50°C.
is detected, a certain period of time (e.g. 2
minutes), the second thermistor 12-1 detects the temperature again (steps S28, S29). Then, the content amount is determined from the rate of temperature rise over a certain period of time,
The amount of electricity supplied to the rice cooking heater 1 is controlled so that the amount of electricity corresponds to the amount of contents, and the process moves to the next power control mode (step S30).

In the power control mode (Figure 12), the amount of electricity is controlled and the amount of electricity is controlled for a certain period of time (for example, 4 minutes).
It is heated by electricity (step S32). Normally, it boils at this stage, but since it remains in the water, the temperature detected by the first thermistor 6-1 never exceeds the boiling point of water. If in this power control mode,
If the first thermistor 6-1 detects 137°C or higher,
It is determined that the inner pot is empty, and the process shifts to the warming mode (step S31).

After a certain period of time has elapsed in step S32, the boiling maintenance mode is entered and the power is reduced to 70% of the control power value (step S33). Eventually, as boiling is completed and the water disappears, the temperature of the rice will rise, so
If the thermistor 6-1 detects a temperature of 137°C or higher, the process shifts to the next uneven mode (step S34). if,
If an abnormality occurs in the first thermistor 6-1 and 137° C. is not detected, a transition is made to the uneven mode after a certain period of time (for example, 25 minutes) has elapsed after starting the boiling maintenance mode (step S35).

The normal rice cooking mode will be explained with reference to FIG.

In this mode, the electric power applied to the rice cooking heater 1 is set to 70% of the maximum electric power, and the rice is heated for a certain period of time _T1 . Regardless of the state of the temperature detection means, when this time _T1 has elapsed, the electric power is stopped (steps S37 and S38). ). This time _T1 is set to a time during which the rice can be cooked to a certain extent that no re-cooking is necessary and the rice cooker does not heat up to the operating temperature of the temperature fuse.

As explained above, in the present invention, when a certain period of time has elapsed from the start of the heating mode with constant power, the power supply is stopped regardless of the state of the temperature detection device, so abnormal temperature rise in the rice cooker It is possible to prevent thermal damage to the vessel body caused by cooking and re-cooking due to poor rice cooking.

[Brief explanation of drawings]

Figure 1 is a schematic diagram explaining the configuration of the present invention, Figure 2 is a schematic diagram explaining the configuration of the present invention.
The figure is a schematic sectional view showing one embodiment of the present invention, FIG. 3 is a main circuit diagram of one embodiment, FIG. 4 is a diagram showing a panel of a control unit used in one embodiment, and FIG. 5 is one embodiment. Figures 6 to 13 showing the rice cooking program in the example are flowcharts showing the operation of one embodiment. 1... Rice cooking heater, 2... Inner pot, 4... Heat retention heater, 6, 12... Temperature detection means, 6-1, 12
-1... Thermistor, 7... Rice cooking mode setting means, 8... Rice cooking mode control means, 9... Timing means, 10... Heater energization amount control means, 11... Switch means, 21... Microcomputer.

Claims (1)

[Scope of Claims] 1. A rice cooker control device having a first mode in which rice is heated and cooked according to a predetermined program, and a second mode in which rice is heated and cooked with constant electric power. , a timer means that starts a timing operation from the start of heating the rice cooker when in the second mode, and a control means that stops heating the rice cooker when a preset time in the timer means has elapsed from the start of the heating. A rice cooker control device comprising: