JP5256830B2 - Cooker - Google Patents

Description

  The present invention relates to a cooker having a backup power source when power supply from a power plug is stopped.

  Conventionally, in cookers such as automatic bread machines and rice cookers, when the primary battery is installed and the power supply from the power plug is stopped, the microcomputer is operated with the primary battery, and the current time and settings are set. (For example, refer to Patent Document 1).

FIG. 4 shows a circuit diagram of a conventional automatic bread maker described in Patent Document 1. As shown in FIG. As shown in FIG. 4, the microcomputer 2 has a menu setting function and a current time measuring function. The display device 3 is composed of a liquid crystal display device, and displays a menu, cooking status, current time, and the like. The switch 4 is used for setting menus, starting cooking, and the like. The primary battery 5 supplies power for backup to the microcomputer 2. The ZVP detection circuit 7 detects a sine wave of power supply from the power plug 1.

In the above configuration, when power is supplied from the power plug 1, the “current time” is displayed on the display device 3 by a signal from the microcomputer 2 (standby state). Next, when the power plug 1 is removed and the power supply is stopped, the sine wave signal from the ZVP detection circuit 7 disappears, and a signal from the microcomputer 2 causes the display device 3 to “power off” and “ Switch to “Current Time” display. Further, the power supply to the microcomputer 2 is continued by the primary battery 5.
JP-A-9-173215

  However, in the above-described conventional configuration, in the power supply by the primary battery 5 when the power supply from the power plug 1 is stopped, the primary battery 5 is always driven in order to drive the microcomputer 2 by the supply from the primary battery 5. The consumption current of was increasing.

  An object of the present invention is to solve the above-described conventional problems, and to reduce power consumption of a primary battery by supplying power from an electric double layer capacitor and a primary battery when power supply from a power plug is stopped.

In order to achieve the above object, the present invention provides a microcomputer having a menu setting function and a time keeping function, a power plug for supplying power to the microcomputer, an electric double layer capacitor for supplying power to the microcomputer, and a primary. A battery and a display device. When power supply from the power plug is stopped, power is first supplied from the electric double layer capacitor to the microcomputer, and then power is supplied from the primary battery to the microcomputer. When the power is supplied from the electric double layer capacitor to the microcomputer, the state of power supply from the electric double layer capacitor to the microcomputer is displayed on the display device, and the primary battery is transferred to the microcomputer. When the power supply of Stop showing the shown device, as is obtained by configuration.

  Thus, when the power supply from the power plug is stopped, the current consumption of the primary battery can be reduced by supplying power from the electric double layer capacitor and the primary battery.

  The cooking device of the present invention can reduce the current consumption of the primary battery by supplying power from the electric double layer capacitor and the primary battery when the power supply from the power plug is stopped.

According to a first aspect of the present invention, there is provided a microcomputer having a menu setting function and a current time counting function, a power plug for supplying power to the microcomputer, an electric double layer capacitor and a primary battery for supplying power to the microcomputer, and a display device And when the power supply from the power plug is stopped, the power is first supplied from the electric double layer capacitor to the microcomputer, and then the power is supplied from the primary battery to the microcomputer. When power is supplied from the capacitor to the microcomputer, the display device displays the state when power is supplied from the electric double layer capacitor to the microcomputer.
When the power supply from the primary battery to the microcomputer is stopped, the display to the display device is stopped, and when the power supply from the power plug is stopped, By supplying power from the primary battery and the electric double layer capacitor to the microcomputer, the current consumption of the primary battery can be reduced.

  Embodiments of the present invention will be described below with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 shows a circuit diagram of a cooking device according to Embodiment 1 of the present invention, and FIG. 2 shows a block diagram of the cooking device. In this embodiment, an automatic bread maker will be described.

  As shown in FIG. 2, the power plug 1 supplies power to an automatic bread maker (cooker), and the heater 8 heats the baking chamber including the bread container. The motor 9 rotates the blades to knead the dough in the bread container. The thermistor 10 detects the temperature in the firing chamber, and the control means 15 drives the heater 8 and the motor 9 by supplying power from the power plug 1 and includes a microcomputer.

  Next, as shown in FIG. 1, the microcomputer 2 constitutes the above-described control means 15 and has a menu setting function and a current time counting function. The display device 3 is composed of a liquid crystal display device, and displays a menu, cooking status, current time, and the like. The switch 4 is operated when setting menus or starting cooking. The primary battery 5 supplies power for backup to the microcomputer 2, and the electric double layer capacitor 6 supplies power for backup to the microcomputer 2 in the same manner. When power supply from the power plug 1 is stopped, The electric double layer capacitor 6 and the primary battery 5 are configured to supply power to the microcomputer 2. The ZVP detection circuit 7 detects a sine wave of power supply from the power plug 1.

Here, when power supply from the power plug 1 is stopped, power is first supplied from the electric double layer capacitor 6 to the microcomputer 2, and then power is supplied from the primary battery 5 to the microcomputer 2. Further, from the electric double layer capacitor 6 to be displayed on the display device 3 a state when the power supply to the microcomputer 2, in the state when the power supply to the microcomputer 2 from the primary battery 5, the display device 3 The display to be stopped is stopped.

  In the above configuration, the operation when the power supply from the power plug 1 is stopped will be described.

  First, when power is supplied from the power plug 1, the “current time” is displayed on the display device 3 by a signal from the microcomputer 2 (standby state). In addition, the electric double layer capacitor 6 is charged. When the power plug 1 is removed and the power supply is stopped, the signal of the sine wave from the ZVP detection circuit 7 disappears, and the signal from the microcomputer 2 causes the display device 3 to “power off” and “current time”. To display (backup 1 state). Further, the power supply to the microcomputer 2 is continued by the electric charge of the electric double layer capacitor 6. Here, the voltage of the electric double layer capacitor 6 is set to 5.5V and the electric capacity is set to 1F (Farad). In order to maintain 3V as a driving power source of the microcomputer 2, a voltage up to 4V is required. Become. Further, the load current of the microcomputer 2 when the power plug 1 is stopped is 20 μA, and the driveable time t by the electric double layer capacitor 6 of the microcomputer 2 is about 75000 seconds according to the following equation. About 75000 seconds is about 21 hours.

    t = C × (V0−V1) / I = 1 × (5.5-4) /0.00002=75000 When the power supply by the electric double layer capacitor 6 exceeds 21 hours, the power supply of the microcomputer 2 is driven. As a result, 3V becomes impossible, and the driving to the primary battery 5 is switched, and the display device 3 is turned off by the microcomputer 2 (backup 2 state). In this state, by turning off the display device 3, the load current of the microcomputer 2 is reduced and the current consumption of the primary battery 5 is reduced. Here, when the power plug 1 is connected again to the power outlet and switched to power supply, “current time” is displayed on the display device 3 by a signal from the microcomputer 2 (standby state). In addition, charging of the electric double layer capacitor 6 is resumed.

  Even in the backup 1 state and the backup 2 state, since the microcomputer 2 measures the time in order to maintain the current time, a load current is generated.

  Since the cooking time in the automatic bread machine is 4 hours, even if the automatic bread machine is driven every day for 4 hours and the power plug 1 is turned off at other times, the current consumption of the primary battery 5 Can be reduced.

  Further, since the primary battery 5 can be removed, the primary battery 5 can be replaced even when the current capacity of the primary battery 5 is lost.

  As described above, in the present embodiment, when the power supply from the power plug 1 is stopped, the electric double layer capacitor 6 and the primary battery 5 are configured to supply power to the microcomputer 2. When the power supply is stopped, the current consumption of the primary battery 5 can be reduced by supplying power from the primary battery 5 and the electric double layer capacitor 6 to the microcomputer 2.

  Further, when power supply from the power plug 1 is stopped, power is first supplied from the electric double layer capacitor 6 to the microcomputer 2, and then power is supplied from the primary battery 5 to the microcomputer 2. 5 can be further reduced.

  In addition, since the state when power is supplied from the electric double layer capacitor 6 or the primary battery 5 to the microcomputer 2 is displayed on the display device 3, the user currently supplies power using the electric double layer capacitor 6. Or whether the primary battery 5 is supplying power.

  Further, since the display on the display device 3 is stopped when the power is supplied from the primary battery 5 to the microcomputer 2, the current consumption of the primary battery 5 can be further reduced.

  In the present embodiment, the voltage of the electric double layer capacitor 6 is 5.5 V, the electric capacity is 1 F, and the load current of the microcomputer 2 is 20 μA. However, these values are merely examples, and the present invention is not limited thereto. Absent.

(Embodiment 2)
FIG. 3 shows a circuit diagram of the cooking device in the second embodiment of the present invention. In the present embodiment, an automatic bread maker will be described.

As shown in FIG. 3, the switching circuit 11 switches the power supply from the electric double layer capacitor 6 or the primary battery 5 according to a signal from the microcomputer 2. At this time, the power supply switching timing of the primary battery 5 is varied according to the charging time of the electric double layer capacitor 6. Other configurations are the same as those of the first embodiment, and the same reference numerals are given and description thereof is omitted.

  In the above configuration, the operation when the power supply from the power plug 1 is stopped will be described.

  First, when power is supplied from the power plug 1, the “current time” is displayed on the display device 3 by a signal from the microcomputer 2 (standby state). In this state, the electric double layer capacitor 6 is charged because the electric double layer capacitor 6 and the power supply circuit are connected by the switching circuit 11 according to the signal of the microcomputer 2. When the power plug 1 is removed and the power supply is stopped, the sine wave signal from the ZVP detection circuit 7 disappears, and the signal from the microcomputer 2 causes the display device 3 to display “capacitor on” and “current time”. Switch to display (backup 1 status). Further, the microcomputer 2 starts measuring time after changing to the backup 1 state. Further, in this state, since the electric double layer capacitor 6 and the power supply circuit are continuously connected by the switching circuit 11 according to the signal of the microcomputer 2, the electric double layer capacitor 6 supplies power to the microcomputer 2. Will continue. Here, the voltage of the electric double layer capacitor 6 is 3V and the electric capacity is set to 2F. In order to maintain 2V as a driving power source for the microcomputer, a voltage of at least 2.5V is required. Further, the load current of the microcomputer 2 when the power plug 1 is stopped is 20 μA, and the driveable time by the electric double layer capacitor 6 of the microcomputer 2 is about 50000 seconds according to the following equation. About 50000 seconds is about 14 hours.

t = C × (V0−V1) / I = 2 × (3-2.5) /0.00002=50000
When the time count of the microcomputer 2 exceeds 10 hours, the connection of the power source is switched from the electric double layer capacitor 6 to the primary battery 5 by the switching circuit 11 by the signal of the microcomputer 2. Further, the microcomputer 2 switches the display device 3 to display of “battery on” and “current time” (backup 2 state).

  Here, the timing at which the connection of the power source is switched from the electric double layer capacitor 6 to the primary battery 5 is switched in 10 hours, but the power supply of the primary battery 5 is switched according to the charging time of the electric double layer capacitor 6. The timing is variable, and is actually determined by the following relationship.

  If the charging time in the standby state exceeds 30 minutes, it is 10 hours. If the charging time is 20 minutes or more to less than 30 minutes, it is 6 hours. If the charging time is 10 minutes or more to less than 20 minutes, 2 hours. It becomes. If the charging time is less than 10 minutes, it is set to 0 hour.

  As described above, in the present embodiment, by using the switching circuit 11 that switches the power supply from the electric double layer capacitor 6 or the primary battery 5 by the microcomputer 2, the electric double layer capacitor 6 is located near the microcomputer 2. Therefore, the withstand voltage of the electric double layer capacitor 6 can be reduced, and the electric double layer capacitor 6 can be configured at low cost, and the current consumption of the primary battery 5 can be reduced.

Also, depending on the charging time of the electric double layer capacitor 6, since so as to vary the switching timing of the power supply of the primary battery 5, depending on the charging time of the electric double layer capacitor 6, the switching timing of the primary battery 5 Can be switched to power supply to the primary battery 5 more accurately, so that the current consumption of the primary battery 5 can be reduced without waste.

In the present embodiment, the voltage of the electric double layer capacitor 6 is 3 V, the electric capacity is 2 F, and the load current of the microcomputer 2 is 20 μA. However, these values are merely examples, and the present invention is not limited thereto.

  As described above, the cooker according to the present invention can reduce the current consumption of the primary battery by supplying power from the electric double layer capacitor and the primary battery when the power supply from the power plug is stopped. It is useful as a cooking device having a backup power source when the power supply from is stopped.

Circuit diagram of cooker in Embodiment 1 of the present invention Block diagram of the cooker Circuit diagram of cooker in Embodiment 2 of the present invention Circuit diagram of conventional cooker

1 Power plug 2 Microcomputer 5 Primary battery 6 Electric double layer capacitor

Claims (1)

A microcomputer having a menu setting function and a current time counting function, a power plug for supplying power to the microcomputer, an electric double layer capacitor and a primary battery for supplying power to the microcomputer, and a display device ,
When power supply from the power plug is stopped, power is first supplied from the electric double layer capacitor to the microcomputer, and then power is supplied from the primary battery to the microcomputer.
When power is being supplied from the electric double layer capacitor to the microcomputer, the state of power supply from the electric double layer capacitor to the microcomputer is displayed on the display device, and from the primary battery to the microcomputer The cooker characterized by stopping display on the display device when power is being supplied .

Images